A novel nervous system-specific transmembrane proteasome complex that modulates neuronal signaling through extracellular signaling via brain activity peptides

ABSTRACT

The inventors surprisingly found that neural stimulation caused the synthesis and degradation of proteins into peptides which were then secreted into the cell media within minutes of stimulation by a novel neural-specific and membrane bound proteasome (neuronal membrane proteasome or NMP) that is transmembrane in nature. These secreted, activity-induced, proteasomal peptides (SNAPPs) range in size from about 500 Daltons to about 3000 Daltons. Surprisingly none of the peptides appear to be those previously known to have any neuronal function. Moreover, these SNAPPs have stimulatory activity and are heretofore a new class of signaling molecules. Moreover, the NMP appears to play a highly significant role in aspects of neuronal signaling known to be critical for neuronal function. The inventors have gone on to develop all tools to study this novel mechanisms including protocols and practice for generation and purification of SNAPPs as well as a new and specific inhibitor of the NMP allowing for selective control of this process in the nervous system. The present invention provides methods of making and using these SNAPPs for both laboratory and clinical purposes, the screening for molecules which modulate NMP function in vivo and in vitro, and methods for diagnosis of NMP related diseases.

REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional PatentApplication No. 62/114,758, filed on Feb. 11, 2015, which is herebyincorporated by reference for all purposes as if fully set forth herein.

STATEMENT OF GOVERNMENTAL INTEREST

This invention was made with government support under grant no.1R01MH102364, awarded by the National Institutes of Health. The U.S.government has certain rights in the invention.

BACKGROUND OF THE INVENTION

The ability to convert transient stimuli from the extracellularenvironment into long-term changes in neuronal function is central to ananimal's capacity to adapt and learn from its environment. This ismediated through sensory organs which transduce physical and chemicalstimuli into precise patterns of neuronal activity that elicit specificchanges in the structure and function of the nervous system. Insightinto the mechanisms that underlie these activity-dependent changes hasbeen facilitated by the discoveries of many laboratories over the lastseveral decades demonstrating that neurotransmitters released atneuronal synapses drive proteasome dependent protein degradation (J BiolChem 284, 26655 (2009); Nat Neurosci 6, 231 (2003)). Consistent with arole for neural activity in regulating protein degradation, theproteasome localize to sites of synaptic activity (Nature 441, 1144(2006)). This regulation is central to the ability of a neuron toappropriately respond to stimuli, as inhibition of protein degradationimpairs a host of neuronal functions, ranging from plasticity at theAplysia sensorimotor synapse to cell migration, neurotransmission, andphysiology in the mammalian nervous system (Neuron 32, 1013-1026, 2001;Neuron 52, 239-245, 2006; Cell 89, 115-126, 1997; J Neurosci 26,11333-11341, 2006) including the maintenance of long-term potentiation,a critical cellular mechanism underlying learning and memory (Neuron 52,239 (2006); Nat Neurosci 9, 478 (2006)). Moreover, mutations incomponents of protein degradation machinery cause profound defects inhuman cognitive function (Biochim Biophys Acta 1843, 13 (2014); Nat RevGenet 8, 711 (2007)).

However, roles for proteasome function in the nervous system are morecomplex than they may appear. Proteasome function is required forcertain aspects of nervous system function over long timescales (hoursto days), such as synaptic remodeling and cell migration (Nat Neurosci6, 231-242, 2003; Science 302, 1775-1779, 2003). Contrastingly,proteasome function is also required for activity-dependent neuronalprocesses over very short timescales (seconds to minutes), such asregulating the speed and intensity of neuronal transmission or themaintenance of long-term potentiation (Nature 441, 1144-1148, 2006;Neuroscience 169, 1520-1526, 2010; J Biol Chem 284, 26655-26665, 2009;Learn Mem 15, 335-347, 2008; J Neurosci 26, 4949-4955, 2006; J Neurosci30, 3157-3166, 2010).

Proteasomes are heterogeneous multisubunit catalytic complexes thatconsist of a core 20S stacked ring of α/β subunits with a α₇β₇β₇α₇architecture, and can be associated with 19S or 11S regulatorycap-particles to form a 26S proteasome (Ann. Rev Biochem 65, 801-847,1996). While the natural behavior of 26S capped proteasomes is tomediate ATP-dependent degradation of ubiquitinated proteins, 20Suncapped proteasomes do not require ubiquitin or ATP for their catalyticfunction (Biomolecules 4, 862-884, 2014; EMBO J 17, 7151-7160, 1998;Proc Natl Acad Sci USA 95, Proc Natl Acad Sci USA 95, 2727-27302727-2730, 1998) Recent studies have shown that 20S proteasomes may havekey biological functions separate from the canonical 26Subiquitin-proteasome degradation pathway, particularly in clearingunstructured proteins and in degrading proteins during cellular stress(Ben-Nissan and Sharon, 2014). Despite extensive studies on proteasomefunction in neuronal signaling, the role of the 20S proteasome in thenervous system has remained unknown.

Critically, the functional studies addressing the role for proteasomesin the nervous system have either failed to discriminate between 20S and26S proteasomes through the use of pan-proteasome inhibitors such asMG-132 or lactacystin, or have focused on the 26S proteasome throughaltering the ubiquitination pathway. Despite these and other efforts tounderstand the role of proteasomes in the nervous system, distinctproteasomes that potentially function independent of their proteostaticrole to mediate rapid neuronal signaling have not been discovered.Therefore, we considered that taking an unbiased approach to evaluatingproteasomes in the nervous system, without bias for 20S or 26Sproteasomes, would provide a means to identify unique proteasomes thatcould possibly have acute signaling functions.

There exists an unmet need for better understanding protein degradationin neurons and its link to cognitive function and neuronal signaling inhealth and disease.

SUMMARY OF THE INVENTION

The present inventors made the surprising observation that acuteaddition of the proteasome inhibitor MG-132 onto neurons suppressedneuronal activity-induced calcium signaling within seconds. Sinceshort-term inhibition of the proteasome presumably cannot meaningfullychange the overall protein landscape, it was unclear how proteasomes canrapidly alter neuronal function. Thus, the inventors reasoned that anunidentified function for proteasomes in the nervous system must exist.

The present inventors' investigation revealed a novel neuronal-specific20S proteasome complex that was expressed at neuronal plasma membranesand exposed to the extracellular space. It was found that the activityof this novel neural membrane bound proteasome (NMP) convertedintracellular proteins into extracellular peptides that rapidly inducedneuronal signaling. Specific inhibition of this NMP through a novelmembrane-impermeable proteasome inhibitor rapidly attenuatedactivity-induced neuronal function. These findings identify a newsignaling modality in the nervous system and unveil the possibility thatthe membrane proteasome may be responsible for the previously observeddecades of research showing that acute proteasome-mediated effects onnervous system function.

The present inventors monitored the fate of synthesized proteins andfound that degradation of proteins by the NMP produced peptides whichwere directly released into the cell media. Hypothesizing that the NMPmay play a role in neuronal activity-dependent mechanisms of nervoussystem function the inventors found that this release was suppressedwhen neuronal activity was blocked. Consistent with this finding, therelease of these peptides into the media was dramatically enhanced inresponse to neuronal stimulation. These secreted, neuronalactivity-induced, proteasomal peptides (SNAPPs) range in size from about500 Daltons to about 3000 Daltons. Surprisingly none of these peptidesproduced by the NMP appear to be those previously known. Moreover, theseSNAPPs have stimulatory activity and are heretofore a new class ofsignaling molecules.

Taken together this discovery defines a new modality of criticalneuronal communication through production of biologically meaningfulpeptides, SNAPPs, that requires the function of a novel neuronalspecific transmembrane proteasome, NMP. Changes in the NMP level andpossibly activity greatly impact SNAPP production and activity dependentneuronal signaling critical for nervous system function.

The present inventors used their developed protocols and reagents todetermine whether the NMP was disrupted in various neurodegenerativedisorders. They found decreased NMP levels in AD human brains and invitro model systems for AD. They found decreased NMP in Huntingtondisease mouse models as well. These data are consistent with changes inthe NMP level contributing to neurodegeneration and/or serving as abiomarker for detecting the development of these or other NMP associateddisorders.

In accordance with an embodiment, the present invention provides amethod for diagnosing a NMP associated disease or disorder of neuronalcells in a subject comprising: a) obtaining a sample of neuronal tissuefrom the subject; b) isolating the surface proteins of the neuronaltissue; c) analyzing the surface proteins of b) for the quantity ofexpression of one or more 20S protein core subunit proteins; d)providing a reference neuronal tissue sample; e) comparing the quantityof expression of one or more 20S protein core subunit proteins from thesample of a) to the quantity of expression of one or more 20S proteincore subunit proteins from the reference sample; and f) identifying thesubject as having a NMP associated disease or disorder of neuronal cellswhen the quantity of expression of one or more 20S protein core subunitproteins from the neuronal tissue sample of the subject is significantlygreater or less than the quantity of expression of one or more 20Sprotein core subunit proteins from the reference sample.

In accordance with an embodiment, the present invention provides amethod for diagnosing degenerative disease or disorder of neuronal cellsin a subject comprising: a) obtaining a sample of neuronal tissue fromthe subject; b) isolating the surface proteins of the neuronal tissue;c) analyzing the surface proteins of b) for the quantity of expressionof one or more 20S protein core subunit proteins; d) providing areference neuronal tissue sample; e) comparing the quantity ofexpression of one or more 20S protein core subunit proteins from thesample of a) to the quantity of expression of one or more 20S proteincore subunit proteins from the reference sample; and f) identifying thesubject as having a degenerative disease or disorder of neuronal cellswhen the quantity of expression of one or more 20S protein core subunitproteins from the neuronal tissue sample of the subject is significantlyless than the quantity of expression of one or more 20S protein coresubunit proteins from the reference sample.

In accordance with another embodiment, the present invention provides amethod for identifying a human subject as having a NMP associateddisease or disorder of neuronal cells comprising: a) obtaining abiological sample from said human subject; b) quantifying the amount ofSNAPPs in the sample from a); c) comparing the amount of SNAPPs in thesample from a) to the amount of SNAPPs in samples from normal controlsubjects; and d) identifying the subject as having a NMP associateddisease or disorder of neuronal cells when the quantity of SNAPPs in thesample from a) is significantly greater or less than the quantity ofSNAPPs in samples from normal control subjects.

In accordance with an embodiment, the present invention provides acomposition comprising one or more secreted cortical neuronal-activityinduced proteasomal peptides (SNAPPs).

In accordance with another embodiment, the present invention provides acomposition comprising one or more secreted neuronal-activity inducedproteasomal peptides (SNAPPs) and at least one detectable moiety.

In accordance with still another embodiment, the present inventionprovides a method for making secreted neuronal-activity inducedproteasomal peptides (SNAPPs) comprising the steps of: a) providing anin vitro culture of a plurality of cortical neurons in a growth medium;b) stimulating the neurons for a period of time sufficient to allowsecretion of SNAPPs into the growth medium; c) removing at least aportion of the growth medium containing the SNAPPs.

In accordance with a further embodiment, the present invention providesa method for screening for compounds which stimulate NMP and subsequentproduction of secreted cortical neuronal-activity induced proteasomalpeptides (SNAPPs) comprising the steps of: a) providing a plurality ofin vitro cultures comprising a plurality of neurons in a growth medium;b) providing one or more test cultures by contacting the neurons of atleast a first culture with a test compound for a period of timesufficient to stimulate NMP and allow production of SNAPPs into thegrowth medium; c) providing a negative control by contacting the neuronsof at least a second culture for a period of time sufficient with acarrier or vehicle which will not stimulate NMP mediated production ofSNAPPs into the growth medium; d) removing at least a portion of thegrowth medium of the cultures of b) and c) and performing an isolationstep to purify the SNAPPs from the cultures of b) and c); e) quantifyingthe amount of SNAPPs isolated in e) from the cultures of b) and c); andf) determining that the test compound is a stimulator of NMP mediatedSNAPP production when the quantity of SNAPPs isolated from b) aresignificantly increased when compared with the amount of SNAPPs in c).

In accordance with a further embodiment, the present invention providesa method for screening for compounds which stimulate NMP and subsequentproduction of secreted cortical neuronal-activity induced proteasomalpeptides (SNAPPs) comprising the steps of: a) administering to a subjecta test compound for a period of time sufficient to stimulate NMP andallow production of SNAPPs in the neurons of the subject; b) providing anegative control by administering to at least a second subject for aperiod of time sufficient with a carrier or vehicle which will notstimulate NMP mediated production of SNAPPs in the neurons of the secondsubject; c) obtaining a biological sample from a) and b) and performingan isolation step to purify the SNAPPs from the biological samples of b)and c); d) quantifying the amount of SNAPPs isolated in e) from thebiological samples of a) and b); and e) determining that the testcompound is a stimulator of NMP mediated SNAPP production when thequantity of SNAPPs isolated from the biological samples of a) aresignificantly increased when compared with the amount of SNAPPs isolatedfrom the biological samples of b).

In accordance with yet another embodiment, the present inventionprovides a method for screening for compounds which inhibit NMP mediatedproduction of secreted neuronal-activity induced proteasomal peptides(SNAPPs) comprising the steps of: a) providing a plurality of in vitrocultures comprising a plurality of neurons in a growth medium; b)providing one or more test cultures by contacting the neurons of atleast a first culture with a test compound and with a known neuronalstimulant of NMP for a period of time sufficient to allow NMP mediatedproduction of SNAPPs into the growth medium; c) providing a negativecontrol by contacting the neurons of at least a second culture for aperiod of time sufficient with a carrier or vehicle which will notstimulate NMP and secretion of SNAPPs into the growth medium; d)providing a positive control by stimulating the neurons of a thirdculture for a period of time sufficient with a known neuronal stimulantto allow NMP mediated production of SNAPPs into the growth medium; e)removing at least a portion of the growth medium of the cultures of b)to d) and performing an isolation step to purify the SNAPPs from thecultures of b) to d); f) quantifying the amount of SNAPPs isolated in e)from the cultures of b) to d); and g) determining that the test compoundis an inhibitor of NMP mediated SNAPP production when the quantity ofSNAPPs isolated from b) are significantly reduced when compared with theamount of SNAPPs in c) and/or d).

In accordance with another embodiment, the present invention provides amethod for screening for compounds which inhibit NMP mediated productionof secreted neuronal-activity induced proteasomal peptides (SNAPPs) in asubject comprising the steps of: a) administering to a first subject atest compound thought to be an inhibitor of NMP for a period of timesufficient to allow NMP mediated production of SNAPPs in the subject; b)providing a negative control by administering to at least a secondsubject for a period of time sufficient with a carrier or vehicle whichwill not stimulate NMP and secretion of SNAPPs in the second subject; c)providing a positive control by administering to at least a thirdsubject for a period of time sufficient with a known neuronal stimulantto allow NMP mediated production of SNAPPs in the subject; d) obtainingbiological samples from the subjects of a) to c) and performing anisolation step to purify the SNAPPs from the biological samples of a) toc); e) quantifying the amount of SNAPPs isolated in d) from thebiological samples of a) to c); and f) determining that the testcompound is an inhibitor of NMP mediated SNAPP production when thequantity of SNAPPs isolated from the biological samples of a) aresignificantly reduced when compared with the amount of SNAPPs isolatedfrom the biological samples of b) and/or c).

In accordance with an embodiment, the present invention provides amethod for inhibiting secreted neuronal-activity induced proteasomalpeptides (SNAPPs) in a neuronal cell or population of cells comprisingcontacting the cell or population of cells with an effective amount ofat least one NMP inhibitor for a time sufficient to inhibit secretion ofSNAPPs.

In accordance with another embodiment, the present invention provides amethod for identifying and targeting activated neurons in vitrocomprising: a) providing a plurality of in vitro cultures comprising aplurality of neurons in a growth medium; b) stimulating at least one ormore of the cultures with a stimulant; c) removing the growth medium ofthe plurality of in vitro cultures; d) fixing the plurality of in vitrocultures; e) staining the plurality of in vitro cultures with at leastone or more SNAPP compositions as described herein; f) quantifying thedetectable moiety of the compositions of e) using imaging and/orradiography; g) identifying the activated neurons as those neurons fromstimulated in vitro cultures which have a significantly increased amountof detectable signal from the detectable moiety compared to the amountof detectable signal in neurons from in vitro cultures which were notstimulated; and h) using the ability of SNAPPs to bind to activatedneurons to target a conjugated molecule to activated neurons.

In accordance with an embodiment, the present invention provides amethod for identifying and targeting activated neurons in vivo using theability of SNAPPs to bind to activated neurons to target a conjugatedmolecule to activated neurons, comprising: a) administering to theneuronal tissue of a mammal an effective amount of at least one or moreSNAPP compositions as described herein, wherein the imaging agent is aSPECT or PET, or magnetic resonance imaging agent; b) imaging theneuronal tissue of the mammal; c) identifying the activated neurons asthose neurons which have a significantly increased amount of detectablesignal from the detectable moiety compared to the amount of detectablesignal from other neurons in the tissue.

As such, in accordance with an embodiment, the present inventionprovides a method for identifying a neuron or population of neurons ashaving aberrant or dysregulated NMP function comprising: a) providing atleast one first in vitro culture comprising a neuron or population ofneurons of interest; b) providing at least one second in vitro normal orcontrol cultures comprising a wild type or standard neuron or populationof neurons; c) contacting the neurons of the first and second culturedwith a stimulant compound for a period of time sufficient to allow NMPmediated production of SNAPPs into the growth medium; c) providing anegative control in vitro culture comprising a wild type or standardneuron or population of neurons by contacting the neurons of thenegative control for a period of time sufficient with a carrier orvehicle which will not stimulate NMP mediated production of SNAPPs intothe growth medium; d) removing at least a portion of the growth mediumof the cultures of a) to c) and performing an isolation step to purifythe SNAPPs from the cultures of a) to c); e) quantifying the amount ofSNAPPs isolated in e) from the cultures of a) to c); and f) determiningthat the first in vitro culture of interest has dysregulated NMPfunction when the quantity of SNAPPs isolated from a) are significantlyincreased or decreased when compared with the amount of SNAPPs in b).

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1E show a 20S proteasome is integral to the neuronal plasmamembrane and is catalytically active. (A) Immuno-EM of core catalytic(32 proteasomal subunits in cortical neurons, with representative imagesshown. Inset shows magnified region. Labeled ultrastructures:presynaptic (Pre); postsynaptic (Post); Microtubules (MT); synapticvesicles (SV). Arrows corresponding to immunogold label; cytosolic(white); membrane (red-cytosolic face), (yellow-directly on),(green-extracellular face). Quantification of shown to right (n=84, >300gold-particles). *P<0.01 (two-tailed Student's t-test). Data arepresented as mean±SEM. (B) Proteasome subunits interact with the plasmamembrane. Cortical neurons were fractionated into cytosolic and plasmamembrane components. Plasma membranes were extracted with indicatedsequentially increasing concentrations of detergent. Samples wereanalyzed by immunoblotting using antibodies against indicated proteins.Quantification compared cytosolic signal to that of the combinedmembrane fractions. *P<0.01 (two-tailed Student's t-test). Data arepresented as mean±SEM (n=3). (C) Proteasome subunits fractionate asintegral membrane proteins. Western blots of cytosolic,peripheral-membrane (periph.), and integral-membrane (integ.) proteinsfractions from cortical neurons. (D,E) Proteasomes at membranes aremolecularly distinct, catalytically active, and intact 20S proteasomes.(D) Western blots of purified proteasomes using capped-26S or 20Spurification matrices. Purification was done out of either cytosol (Cyt.Pure) or detergent-extracted plasma membranes (Mem. Pure) from corticalneurons. (E) Purified 20S proteasomes from neuronal cytosol or membranewere incubated with the fluorescent proteasome peptide substrateSUC-LLVY-AMC. Endpoint fluorescence is plotted to reflect activity ofboth 20S and 26S proteasomes. *P<0.01 (two-tailed Student's t-test).Data are presented as mean±SEM (n=3).

FIGS. 2A-2G show that the Neuronal Membrane Proteasome (NMP) issurface-exposed, neuronal-specific, and temporally regulated. (A) Above,Schematic depicting 20S proteasome composition, as well as approachestaken to evaluate whether membrane proteasomes are exposed to theextracellular space. Both the cytosolic and membrane proteasome arelocalized to the neuronal soma and dendrites. Below, immunofluorescenceimages from fixed neurons, either permeabilized (left) ornon-permeabilized, (right) are stained using antibodies againstproteasomal beta subunits and MAP2. (B,C) Proteasomes are exposed to theextracellular space. (B) Proteinase K (PK) was applied onto culturedcortical neurons for the indicated times. Cytosolic or plasma membranefractions subjected to immunoblotting for N-terminal antibody againstGluR1 (N-GluR1), core alpha proteasome subunits (al-7), and Tubulin. (C)Biotinylated proteins from surface biotinylated 14 DIV cortical neuronswere precipitated on streptavidin affinity beads and subjected toimmunoblotting. Inputs are shown to the left of streptavidin pulldown.(D, E) Surface-exposed proteasome expression is unique to nervous systemtissues. (D) Streptavidin pulldown (Strep) done from Neuroblastoma-2A(N2A), HEK293 kidney cell lines (HEK), and cortical neurons (Cort). (E)Streptavidin pulldown (Strep) done from tissues dissected from a P3mouse Cortex (Ctx), Hippocampus (Hip), Olfactory bulb (010, Hind Brain(Brn), Heart (Ht), Lung (Lg), Kidney (Kid), Liver (Lv), Pancreas (Pnc).(F) Surface proteasome expression is temporally regulated. Biotinylatedproteins from surface biotinylated cortical neurons were precipitated onstreptavidin affinity beads and subjected to immunoblotting. Inputs areshown to the left of streptavidin pulldown. Streptavidin pulldown wasdone at the indicated Days In Vitro (DIV). (G) Schematic shows surfacebiotinylation done in neuronal cultures at 7 and 8 DIV. Biotinylatedproteins were precipitated using streptavidin affinity beads and thenanalyzed by LC/MS. Core proteasomal subunits expressed at the surface at8 DIV and not at 7 DIV as shown by mass spectrometry are listed in thetable. Molecular weight and % coverage by mass spectrometry shown.

FIGS. 3A-3D show that the NMP mediates degradation of intracellularproteins into extracellular peptides. (A) Representative autoradiographof lysates from cortical neurons radiolabeled with ³⁵Smethionine/cysteine for 10 minutes in the presence or absence of MG-132.(B) Schematic for collection and purification of extracellular peptides.Media from radiolabeled neurons is collected and purified. Mediacollected from neurons following radiolabeling was subjected to sizeexclusion purification, with or without Proteinase K (PK). Thepercentage of total radioactivity eluting at different sizes is shown.*P<0.01 (two-tailed Student's t-test). Data are presented as mean±SEM(n=3). (C) Rapid efflux of radioactive material out of neuronal cellsinto media depends upon proteasome function. Media collected fromneurons following radiolabeling with or without MG-132 or ATPγS. Liquidscintillation quantification of media at indicated time points is shownnormalized to control at the 10 minute time point; 2 minute time pointshown separately on the bar graph. Media collected from 14 DIV neuronsfollowing radiolabeling without or with MG-132 or ATPγS. *P<0.01(one-way ANOVA). Data represent mean±SEM (n=3). (D) Release ofproteasome-derived peptides in the extracellular space correlates withNMP expression. Experiment performed as described in (C); mediacollected from either 7 DIV or 8 DIV neurons, with or without MG-132.

FIGS. 4A-4F show neuronal activity induces Proteasome-mediateddegradation of synthesized proteins to generate signaling peptides thatare secreted from the neuron. (A) Pulse chase schematic and collectionparadigm for release of radioactive material into media. Following theindicated stimulation and radioactive pulse, cells were rapidly washedwith PBS, and chased into nonradioactive media, either in the presenceof absence of MG-132. White arrowheads indicate times when a 25 μlsample was withdrawn from the media for scintillation analysis.Cumulative data are shown for the 10 minute time course on the left andat the 2 minute time point on the right (n=5, p<0.01). (B) Schematic forcollection, purification, and use of SNAPPs. Following 30 minutes ofstimulation, media containing the stimulation buffer is washed out andreplaced with non-depolarizing collection media. Followingquantification of radioactivity in the media as described above, SNAPPsare purified out of the media (see Examples), and either applieddirectly onto cells or labeled in vitro for tagging. (C) SNAPPs inducecalcium transients. Representative images on the left demonstrate anincrease in fluorescence of a calcium reporter upon addition of SNAPPsto naive GCaMP3-encoding neurons. Quantification is on the right, wherethe first arrowhead indicates when SNAPPs are added and the secondarrowhead indicates time of washout (n=8, p<. 01). Control SNAPPs arepurified from neurons with baseline spontaneous levels of activity. (D)SNAPPs potentiate calcium-sensitive signaling. Western blot ofphosphorylated CamKII, total CamKII, and Actin following addition ofSNAPPs or KCl stimulation for five minutes. Western blot of pERK1/2following incubation with control peptides or SNAPPs and with or withoutpretreatment of peptides with Proteinase K. (E) Labeled SNAPPspreferentially bind stimulated neurons. Unstimulated (control) orstimulated (KCl) neurons were fixed and stained with MAP2 (Green) andlabeled SNAPPs (Magenta). (F) Channelrhodopsin (ChR2) transfectedneurons were stimulated at the indicated frequency for one minute,fixed, and stained with an anti-GFP antibody that is reactive againstChR2 protein (Green) and labeled SNAPPs (Magenta).

FIGS. 5A-5B show developmentally regulated SNAPP release is tightlycorrelated with a proteasome expressed at the neuronal membrane. (A)SNAPP release is developmentally regulated. As described in FIG. 3A,SNAPP release was measured at DIV7 and DIVE. (B) Quantification ofdevelopmentally regulated SNAPP release is shown at 2 minutes.

FIGS. 6A-6D show that the NMP is required for release of extracellularpeptides and modulates neuronal signaling. (A,B) Biotin-epoxomicin doesnot cross neuronal membranes and covalently binds proteasome subunits.(A) Neurons treated with biotin-epoxomicin (Bio-Epox) were separatedinto cytosolic (Cyto) and membrane (Mem) fractions and analyzed bywestern using fluorescent streptavidin. Immunoblots using indicatedantibodies shown below. (B) Immunogold labelling against biotin (yellowarrows) in cultured cortical neurons treated with Bio-Epox, withrepresentative images shown (out of 54). Labeled ultrastructures:presynaptic regions (Pre), postsynaptic regions (Post), Microtubules(MT—black arrowheads), and synaptic vesicles (SV—black arrowheads).Quantification of particles in cytosol and on membrane (right). (C)NMP-specific inhibition blocks release of extracellular peptides. Mediacollected from neurons following radiolabeling, with or withoutBio-Epox. Liquid scintillation quantification of media at indicated timepoints is shown normalized to control at the 10 minute time point; 2minute time point shown separately on bar graph. (D) NMP inhibitionmodulates speed and intensity of neuronal calcium transients.Bicuculline (Bic) added to naïve GCaMP3-encoding neurons, with orwithout Bio-Epox. Representative images (above) and traces ofbicuculline response before and after Bio-Epox addition are plotted.Quantification of normalized fluorescence intensity measurements ofcalcium signals over imaging time course. Average maximum amplitudes areplotted, and include analysis of calcium signaling after treatment withMG-132. *P<0.01 (two-tailed Student's t-test). Data are presented asmean±SEM (b, n=54, >200 gold particles; c, n=3; d, n=2, n=24 neurons,with 18 ROIs analyzed per neuron).

FIG. 7 shows that the NMP expression is conserved in humans and variesacross individuals. Fetal human brains were obtained according toInstitutional Review Board Protocol. Fresh tissue was dissected andsliced and then surface biotinylated. Surface proteins were isolated onstreptavidin beads and subsequently analyzed by western blot. Proteasomesubunits were pulled down on streptavidin beads, whereas cytosolicprotein actin was not. Inputs are shown to the left of the streptavidinpulldown. Expression is fairly consistent across humans, except for onesample that demonstrated much higher expression. Further analysisrevealed that the patient who consented for the procedure was on regularmethadone use for treatment of heroin addiction. These samples were runblinded. Densitometry quantification is shown to the right, withexpression of the NMP normalized to the total amount of proteasome.

FIG. 8 shows that Dysregulation of the NMP in Alzheimer's disease. NMPexpression in mouse cortical neurons treated with a variety ofcompounds, including Aβ1-42. DIV12 mouse neurons were treated with 1 μMAβ1-42 peptide for 12 hours. Following treatment, neurons were surfacebiotinylated, and surface proteins were isolated and analyzed by westernblot. Inputs are shown to the left of the streptavidin pulldown. Notethe significant change in expression of proteasome subunits in thestreptavidin pulldown from Aβ treated neurons.

FIG. 9 shows that NMP expression in samples from post-mortem Humanpatients with Alzheimer's disease. Primary samples from 10 patients wereobtained from the Johns Hopkins Lieber Institute for Brain DevelopmentBrain Bank. All tissue was obtained under their IRB. Samples wereblinded, and then surface biotinylated and lysed. Surface proteins werepulled down on streptavidin beads and analyzed by western blot. Inputsare shown above the streptavidin pulldown. Lower levels of proteasomesubunits were seen in 5 different samples, which were revealed to befrom patients who had Alzheimer's. Samples are labeled underneath aseither AD (+) for AD positive samples or AD (−) for unaffectedindividuals. This blinded approach confirms the ability to use NMPexpression as a diagnostic method for Alzheimer's disease.Quantification is shown to the right, with the levels of the NMPnormalized against the total proteasome levels. * P<0.01, Student'st-test, n=5.

FIG. 10 shows the progression of Alzheimer like symptoms in a mousemodel of the disease. Brains from early stage (3 month old) J20 AD mousemodel (see figure) and wild type mice were treated as in FIG. 4C toisolate the NMP. Samples were run on SDS-PAGE and probed for proteasome,APP and actin. Note that in AD mouse models at early stages of diseaseprogression we observe an increase in NMP as opposed to a decrease whentreating neurons in culture with Abeta or from late stage human ADsamples. This indicates that the NMP is dynamic in nature during priorto and during AD progression and can be specifically studied for itscontribution to AD related phenotypes in these and other mouse models.The NMP is one of the few proteins ever shown to have such a dramaticchange in expression in this AD model so early in development of thedisease.

FIG. 11 shows that Dysregulation of the NMP in a murine model ofHuntington's disease. The striatum was dissected from 6 week agedHuntington transgenic animals. This stage of development is fairly earlyin the disease progression of Huntington in these animals, where fewrobust changes have been detected at this early stage. Dissected tissuewas surface biotinylated, and surface proteins were isolated onstreptavidin beads. Inputs are shown above streptavidin pulldown. Arobust decrease in the levels of the NMP in Huntington positive (+)striatum is shown, and quantified to the right as normalized to inputproteasome levels. These data suggest that the NMP may be an earlydiagnostic in the progression of Huntington's disease.

FIG. 12 is a schematic diagram depicting that certain neurologicaldisorders may in fact, be caused by disruption of NMP function or underexpression of NMP proteins, causing a decrease in SNAPP production whichmay cause under stimulation of neural pathways downstream from theaffected cells. This could also lead to neuronal dysfunction in the formof neuronal communication deficits via decreased synaptic contactsand/or signaling. Conversely, certain disorders may in fact, be causedby an excess of NMP function or over expression of NMP proteins, causingan increase in SNAPP production which may cause over stimulation ofneural pathways downstream from the affected cells, and which may leadto neuronal apoptosis and death.

DETAILED DESCRIPTION OF THE INVENTION

Proteasomes are ubiquitously expressed large multisubunit catalyticcomplexes, generally characterized by a uniform cytoplasmic and nucleardistribution. The present inventors have now identified a nervoussystem-specific proteasome that is bound to the plasma membrane andexposed to the extracellular space. While it is unclear how theseproteasomes bind to and orient themselves within neuronal plasmamembranes, it has been known for decades through in vitro studies thatproteasomes can orient perpendicularly to membranes specificallyenriched in phosphatidylinositol (PI), a key signaling phospholipid thatis notably elevated in the nervous system over other tissues.

The data disclosed herein support the idea that the NMP is either partof a protein pore complex at the plasma membrane or itselftransmembrane. While the presence of a transmembrane proteasome wouldhave been thought to disrupt the equilibrium neuronal resting membranepotential by exposing the cytosol to the extracellular space, thecrystal structure of the uncapped 20S proteasome demonstrates that thiscomplex is gated on both ends and opens only to allow proteins throughfor degradation. Since the inventors have now found that the NMP is a20S proteasome complex, it is thought that it would therefore notdisrupt the neuronal membrane potential if it were a transmembraneprotein.

Based on the studies disclosed herein, the present inventors havesurprisingly found a novel degradation machinery in the neurons thatmediate neuronal activity-induced degradation of synthesized proteins toproduce biologically meaningful peptides. This is, at least in part,mediated through the novel NMP of the present invention in order toproduce signaling peptides important for maintaining and enhancingneuronal activity dependent processes.

The present inventors have found that neuronal activity does not simplypromote global protein degradation, but rather, it promotes proteindegradation exclusively of newly synthesized proteins through the NMPfor the express purpose of generating a new class of signalingmolecules, SNAPPs.

The SNAPPs generated by the NMP of the present invention are a newmodality for neuronal communication. In the release experimentsdescribed herein, the inventors can show that there is some peptiderelease under non-stimulating conditions that is inhibited by MG-132, aknown proteasomal inhibitor, and biotin-epoxomicin, a novel NMP specificinhibitor. It is thought that this is due to baseline asynchronousspontaneous network activity causing some baseline degradation ofproteins by the NMP, leading to peptides being released into the media.These peptides are a diluted pool of SNAPPs, as they do not possess thesame magnitude of signaling capacity as SNAPPs purified from globallystimulated neurons.

Without being held to any particular theory, a possibility is thatSNAPPs associate with MHC complexes. Recent studies have identified thatMHC complexes play key roles in developmental and experience-dependentmechanisms in the nervous system. It is also possible that SNAPPsinteract with other receptors, either known or yet to be identified, orwith cell surface lipids. While these inventive studies specificallytrace those that are secreted in the media, we recognize that based onthe possible mechanism, there may be a variety of SNAPPs that bindimmediately to cells due to them being hydrophobic.

Of note in some aspects of the present invention, is the role forphosphorylated CaMKII in NMP expression. This is particularly intriguinggiven the role for phosphorylated CaMKII in serving as a scaffold forrecruiting the proteasome into dendritic spines, and additionally forits long-known and well-studied role in learning and memory.

The same groups that have demonstrated the role for CaMKII in proteasomerecruitment to spines have also shown that rapid inhibition of theproteasome has profound effects on synaptic signaling and transmission.These effects range from changes in transmission at the Drosophilaneuromuscular synapse, regulation of activity-dependent spine dynamics,and an essential role in maintenance of LTP. In accordance with theinventive compositions and methods, we see a similar rapid and acuterole for the proteasome in mediating SNAPP release (data not shown). Itis important to note that pharmacological inhibitors used in previousstudies take a substantially longer time to achieve functionalinhibition of the cytosolic proteasome, according to data from groupsstudying the kinetics of proteasome inhibitors in neurons. Given thepresent findings, it is thought that at least some of the effects onsynaptic transmission and function demonstrated by older studies may bedue to inhibition of the neuronal membrane proteasome first reported inthis study, and not of the cytosolic proteasome.

In accordance with an embodiment, the present invention provides amethod for diagnosing a NMP associated disease or disorder of neuronalcells in a subject comprising: a) obtaining a sample of neuronal tissuefrom the subject; b) isolating the surface proteins of the neuronaltissue; c) analyzing the surface proteins of b) for the quantity ofexpression of one or more 20S protein core subunit proteins; d)providing a reference neuronal tissue sample; e) comparing the quantityof expression of one or more 20S protein core subunit proteins from thesample of a) to the quantity of expression of one or more 20S proteincore subunit proteins from the reference sample; and f) identifying thesubject as having a NMP associated disease or disorder of neuronal cellswhen the quantity of expression of one or more 20S protein core subunitproteins from the neuronal tissue sample of the subject is significantlygreater or less than the quantity of expression of one or more 20Sprotein core subunit proteins from the reference sample.

As used herein, the term “Neuronal Membrane Proteasome (NMP)” means aneuronal-specific 20S proteasome complex that was expressed at neuronalplasma membranes and exposed to the extracellular space. The NMP isunique to the nervous system and produces SNAPPs into the extracellularspace.

As used herein, the analysis of proteins which are located on the plasmamembrane surface of the neuronal cell, can be performed using manydifferent means known in the art. In an embodiment, the plasma membranefraction is isolated from neurons by lysing them in either a sucrosebuffer or hypotonic lysis buffer. Nuclei were pelleted, and thesupernatant containing plasma membranes was then pelleted at high RPM.Once the supernatant (cytosolic fraction) was set aside, the pellet waswashed 2× with lysis buffer, and then resuspended in lysis buffer withindicated concentrations of detergent. Following a 15-minute incubationin the buffer, samples were spun down. This was repeated for allindicated concentrations of detergent. Membrane association wasdetermined by classic methods of sodium carbonate extraction. Theproteins were visualized by SDS-PAGE methods. Other methods can be used.

As used herein the 20S core proteins associated with the NMP can beidentified and analyzed through the use of an antibodies that detect(32, anti-α1-7 proteasome subunit, anti-α5 proteasome subunit, anti-β1proteasome subunit, anti-β2,5 subunit, anti-β2 proteasome subunit, andanti-Rpt5 proteasome subunit, for example. Other method foridentification are known in the art, and include, for example, surfacebiotinylation methods and mass spectrometry.

In accordance with an embodiment, the present invention provides amethod for diagnosing degenerative disease or disorder of centralnervous system neuronal cells in a subject comprising: a) obtaining abiological sample from said human subject; a) obtaining a sample ofneuronal tissue from the subject; b) isolating the surface proteins ofthe neuronal tissue; c) analyzing the surface proteins of b) for thequantity of expression of one or more 20S protein core subunit proteins;d) providing a reference neuronal tissue sample; e) comparing thequantity of expression of one or more 20S protein core subunit proteinsfrom the sample of a) to the quantity of expression of one or more 20Sprotein core subunit proteins from the reference sample; and f)identifying the subject as having a degenerative disease or disorder ofneuronal cells when the quantity of expression of one or more 20Sprotein core subunit proteins from the neuronal tissue sample of thesubject is significantly less than the quantity of expression of one ormore 20S protein core subunit proteins from the reference sample.

In accordance with another embodiment, the present invention provides amethod for identifying a human subject as having a NMP associateddisease or disorder of neuronal cells comprising: a) obtaining abiological sample from said human subject; b) quantifying the amount ofSNAPPs in the sample from a); c) comparing the amount of SNAPPs in thesample from a) to the amount of SNAPPs in samples from normal controlsubjects; and d) identifying the subject as having a NMP associateddisease or disorder of neuronal cells when the quantity of SNAPPs in thesample from a) is significantly greater or less than the quantity ofSNAPPs in samples from normal control subjects.

In accordance with an embodiment, the present invention provides acomposition comprising one or more SNAPPs.

In accordance with an embodiment, the present invention provides acomposition comprising one or more SNAPPs and at least one agent,detectable moiety or biologically active agent.

As used herein, the term “SNAPP” means proteins and peptides which aresecreted extracellularly by a novel neural membrane bound proteasome(NMP) as the result of neural stimulation. Typically, these SNAPPs aresecreted extracellularly within a few seconds to minutes after neuralstimulation. These SNAPPs range in size from about 500 Daltons to about3000 Daltons.

The term, “amino acid” includes the residues of the natural α-aminoacids (e.g., Ala, Arg, Asn, Asp, Cys, Glu, Gln, Gly, His, Lys, Ile, Leu,Met, Phe, Pro, Ser, Thr, Trp, Tyr, and Val) in D or L form, as well asβ-amino acids, synthetic and unnatural amino acids. Many types of aminoacid residues are useful in the adipokine polypeptides and the inventionis not limited to natural, genetically-encoded amino acids. Examples ofamino acids that can be utilized in the peptides described herein can befound, for example, in Fasman, 1989, CRC Practical Handbook ofBiochemistry and Molecular Biology, CRC Press, Inc., and the referencecited therein. Another source of a wide array of amino acid residues isprovided by the website of RSP Amino Acids LLC.

The term, “peptide,” or “oligopeptide,” as used herein, includes asequence of from four to sixteen amino acid residues in which theα-carboxyl group of one amino acid is joined by an amide bond to themain chain (α- or β-) amino group of the adjacent amino acid. In someembodiments, peptides provided herein for use in the described andclaimed methods and compositions can be cyclic.

The term “imaging agent,” is known in the art. As used herein, the oneor more imaging agents can be any small molecule or radionuclide whichis capable of being detected. In accordance with some embodiments theimaging agent is a fluorescent dye. The dyes may be emitters in thevisible or near-infrared (NIR) spectrum. Known dyes useful in thepresent invention include carbocyanine, indocarbocyanine,oxacarbocyanine, thüicarbocyanine and merocyanine, polymethine,coumarine, rhodamine, xanthene, fluorescein, boron-dipyrromethane(BODIPY), Cy5, Cy5.5, Cy7, VivoTag-680, VivoTag-S680, VivoTag-S750,AlexaFluor660, AlexaFluor680, AlexaFluor700, AlexaFluor750,AlexaFluor790, Dy677, Dy676, Dy682, Dy752, Dy780, DyLight547,Dylight647, HiLyte Fluor 647, HiLyte Fluor 680, HiLyte Fluor 750, IRDye800CW, IRDye 800RS, IRDye 700DX, ADS780WS, ADS830WS, and ADS832WS.

Organic dyes which are active in the NIR region are known in biomedicalapplications. However, there are only a few NIR dyes that are readilyavailable due to the limitations of conventional dyes, such as poorhydrophilicity and photostability, low quantum yield, insufficientstability and low detection sensitivity in biological system, etc.Significant progress has been made on the recent development of NIR dyes(including cyanine dyes, squaraine, phthalocyanines, porphyrinderivatives and BODIPY (borondipyrromethane) analogues) with muchimproved chemical and photostability, high fluorescence intensity andlong fluorescent life. Examples of NIR dyes include cyanine dyes (alsocalled as polymethine cyanine dyes) are small organic molecules with twoaromatic nitrogen-containing heterocycles linked by a polymethine bridgeand include Cy5, Cy5.5, Cy7 and their derivatives. Squaraines (oftencalled Squarylium dyes) consist of an oxocyclobutenolate core witharomatic or heterocyclic components at both ends of the molecules, anexample is KSQ-4-H. Phthalocyanines, are two-dimensional 18π-electronaromatic porphyrin derivatives, consisting of four bridged pyrrolesubunits linked together through nitrogen atoms. BODIPY(borondipyrromethane) dyes have a general structure of4,4′-difluoro-4-bora-3a, 4a-diaza-s-indacene) and sharp fluorescencewith high quantum yield and excellent thermal and photochemicalstability.

Other imaging agents which can be attached to the SNAPPs of the presentinvention include PET and SPECT imaging agents. The most widely usedagents include branched chelating agents such as di-ethylene tri-aminepenta-acetic acid (DTPA),1,4,7,10-tetra-azacyclododecane-1,4,7,10-tetraacetic acid (DOTA) andtheir analogs. Chelating agents, such as di-amine dithiols, activatedmercaptoacetyl-glycyl-glycyl-gylcine (MAG3), and hydrazidonicotinamide(HYNIC), are able to chelate metals like ⁹⁹mTc and ¹⁸⁶Re. Instead ofusing chelating agents, a prosthetic group such asN-succinimidyl-4-¹⁸F-fluorobenzoate (¹⁸F-SFB) is necessary for labelingpeptides with ¹⁸F. In accordance with a preferred embodiment, thechelating agent is DOTA.

In accordance with some embodiments, the present invention provides oneor more SNAPPs wherein the imaging agent comprises a metal isotopesuitable for imaging. Examples of isotopes useful in the presentinvention include Tc-94m, Tc-99m, In-111, Ga-67, Ga-68, Y-86, Y-90,Lu-177, Re-186, Re-188, Cu-64, Cu-67, Co-55, Co-57, Sc-47, Ac-225,Bi-213, Bi-212, Pb-212, Sm-153, Ho-166, or Dy-i66.

In accordance with some embodiments, the present invention provides aSNAPP wherein the reporter portion comprises ¹¹¹In labeled DOTA which isknown to be suitable for use in SPECT imaging.

In accordance with an embodiment, the present invention provides amethod for identifying and targeting activated neurons in vivo using theability of SNAPPs to bind to activated neurons to target a conjugatedmolecule to activated neurons, comprising: a) administering to theneuronal tissue of a mammal an effective amount of at least one or moreSNAPP compositions as described herein, wherein the imaging agent is aSPECT or PET, or magnetic resonance imaging agent; b) imaging theneuronal tissue of the mammal; c) identifying the activated neurons asthose neurons which have a significantly increased amount of detectablesignal from the detectable moiety compared to the amount of detectablesignal from other neurons in the tissue.

In accordance with some other embodiments, the present inventionprovides SNAPPs wherein the imaging agent comprises Gd³⁺ labeled DOTAwhich is known to be suitable for use in MR imaging. It is understood bythose of ordinary skill in the art that other suitable radioisotopes canbe substituted for ¹¹¹In and Gd³⁺ disclosed herein.

In accordance with some embodiments, the present invention providesSNAPPs with wherein the at least one detectable moiety is a mass spectraagent for enhancing or modifying mass spectra, such as coumarin, or anyderivitzation procedure such as 4-sulfophenyl isothiocyanate (SPITC),Edman's reagent, N-terminal modifications such as Quaternary Ammoniumderivatives like methyl iodide to generate trimethylammoniumderivatives, Quarternary Phosphonium derivatives like2-bromoethyl-triphenylphosphonium bromide, molecules that contain HighProton Affinities such as dansyl chloride, C-terminal derivatives suchas 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide (EDC), side-chainderivatives such as 2,4,6-trimethyl pyridinium, or negative chargedderivatives such as pentafluorobenzoyl fluoride that allows for easiercharacterization of mass spectra.

In some embodiments, the present invention provides methods fordetecting neuronal activity using voltage-sensitive dye, whose opticalproperties change during changes in electrical activity of neuronalcells. The spatial resolution achieved by this technique is near thesingle cell level. For example, researchers have used thevoltage-sensitive dye merocyanine oxazolone to map cortical function ina monkey model. Blasdel, G. G. and Salama, G., “Voltage Sensitive DyesReveal a Modular Organization Monkey Striate Cortex,” Nature321:579-585, 1986. However, the use of these kinds of dyes would posetoo great a risk for use in vivo in view of their toxicity.

It will be understood by those of ordinary skill in the art that theSNAPPs of the present invention have the ability to bind activatedneurons, and therefore they can be used as targeting molecules for othertherapies. For example, SNAPPs can be conjugated with another smallmolecule, or biologically active agent, including, drugs, antibodies andthe like. In accordance with some embodiments, the SNAPPs can beconjugated or linked with compounds which stimulate or inhibit neuronalactivity, or which have some other pharmacological effect.

As used herein, the term “biologically active agent” include anycompound, biologics for treating brain-related diseases, e.g. drugs,inhibitors, and proteins. An active agent and a biologically activeagent are used interchangeably herein to refer to a chemical orbiological compound that induces a desired pharmacological and/orphysiological effect, wherein the effect may be prophylactic ortherapeutic. The terms also encompass pharmaceutically acceptable,pharmacologically active derivatives of those active agents specificallymentioned herein, including, but not limited to, salts, esters, amides,prodrugs, active metabolites, analogs and the like. When the terms“active agent,” “pharmacologically active agent” and “drug” are used,then, it is to be understood that the invention includes the activeagent per se as well as pharmaceutically acceptable, pharmacologicallyactive salts, esters, amides, prodrugs, metabolites, analogs etc.

Examples of such classes of compounds include, but are not limited to,cholinergic agonists and antagonists, opiate agonists and antagonists,muscarinic agonists and antagonists, GABAergic agonists and antagonists,parasympathomimetics, sympathomimetics, adrenergic agonists andantagonists, general anesthetics, such as inhalation anesthetics,halogenated inhalation anesthetics, intravenous anesthetics,barbiturates, benzodiazepines, antidepressants, heterocyclicantidepressants, monoamine oxidase inhibitors selective serotoninre-uptake inhibitors tricyclic antidepressants, antimanics,anti-psychotics, phenothiazine antipsychotics, anxiolytics, calciumchannel blockers, and anti-Parkinson's agents such as bromocriptine,levodopa, carbidopa, and pergolide.

It is understood by those of ordinary skill in the art that the imagingagents can be attached to the SNAPPs by use of a linker molecule. Forinstance linking groups having alkyl, aryl, combination of alkyl andaryl, or alkyl and aryl groups having heteroatoms may be present. Forexample, the linker can be a C₁-C₂₀ alkyl, C₂-C₂₀ alkenyl, C₂-C₂₀alkynyl, C₁-C₂₀ hydroxyalkyl, C₁-C₂₀ alkoxy, C₁-C₂₀ alkoxy C₁-C₂₀ alkyl,C₁-C₂₀ alkylamino, di-C₁-C₂₀ alkylamino, C₁-C₂₀ dialkylamino C₁-C₂₀alkyl, C₁-C₂₀ thioalkyl, C₂-C₂₀ thioalkenyl, C₂-C₂₀ thioalkynyl, C₆-C₂₂aryloxy, C₆-C₂₂ acylamino C₂-C₂₀ acyloxy, C₂-C₂₀ thioacyl, C₁-C₂₀ amido,and C₁-C₂₀ sulphonamido.

Compounds are assembled by reactions between different components, toform linkages such as ureas (—NRC(O)NR—), thioureas (—NRC(S)NR—), amides(—C(O)NR— or —NRC(O)—), or esters (—C(O)O— or —OC(O)—). Urea linkagesmay be readily prepared by reaction between an amine and an isocyanate,or between an amine and an activated carbonamide (—NRC(O)—). Thioureasmay be readily prepared from reaction of an amine with anisothiocyanate. Amides (—C(O)NR— or —NRC(O)—) may be readily prepared byreactions between amines and activated carboxylic acids or esters, suchas an acyl halide or N-hydroxysuccinimide ester. Carboxylic acids mayalso be activated in situ, for example, with a coupling reagent, such asa carbodiimide, or carbonyldiimidazole (CDI). Esters may be formed byreaction between alcohols and activated carboxylic acids. Triazoles arereadily prepared by reaction between an azide and an alkyne, optionallyin the presence of a copper (Cu) catalyst.

Protecting groups may be used, if necessary, to protect reactive groupswhile the compounds are being assembled. Suitable protecting groups, andtheir removal, will be readily available to one of ordinary skill in theart.

In this way, the compounds may be easily prepared from individualbuilding blocks, such as amines, carboxylic acids, and amino acids.

It is contemplated that any of the SNAPPs of the present inventiondescribed above can also encompass a pharmaceutical compositioncomprising the SNAPPs and a pharmaceutically acceptable carrier.

In accordance with another embodiment, the present invention provides amethod for identifying and targeting activated neurons in vitrocomprising: a) providing a plurality of in vitro cultures comprising aplurality of neurons in a growth medium; b) stimulating at least one ormore of the cultures with a stimulant; c) removing the growth medium ofthe plurality of in vitro cultures; d) fixing the plurality of in vitrocultures; e) staining the plurality of in vitro cultures with at leastone or more SNAPP compositions as described herein; 0 quantifying thedetectable moiety of the compositions of e) using imaging and/orradiography; g) identifying the activated neurons as those neurons fromstimulated in vitro cultures which have a significantly increased amountof detectable signal from the detectable moiety compared to the amountof detectable signal in neurons from in vitro cultures which were notstimulated; and h) using the ability of SNAPPs to bind to activatedneurons to target a conjugated molecule to activated neurons.

With respect to the SNAPPs described herein, the carrier can be any ofthose conventionally used, and is limited only by physico-chemicalconsiderations, such as solubility and lack of reactivity with theactive compound(s), and by the route of administration. The carriersdescribed herein, for example, vehicles, adjuvants, excipients, anddiluents, are well-known to those skilled in the art and are readilyavailable to the public. It is preferred that the carrier be one whichis chemically inert to the active agent(s), and one which has little orno detrimental side effects or toxicity under the conditions of use.Examples of the carriers include soluble carriers such as known bufferswhich can be physiologically acceptable (e.g., phosphate buffer) as wellas solid compositions such as solid-state carriers or latex beads.

The carriers or diluents used herein may be solid carriers or diluentsfor solid formulations, liquid carriers or diluents for liquidformulations, or mixtures thereof.

Solid carriers or diluents include, but are not limited to, gums,starches (e.g., corn starch, pregelatinized starch), sugars (e.g.,lactose, mannitol, sucrose, dextrose), cellulosic materials (e.g.,microcrystalline cellulose), acrylates (e.g., polymethylacrylate),calcium carbonate, magnesium oxide, talc, or mixtures thereof.

For liquid formulations, pharmaceutically acceptable carriers may be,for example, aqueous or non-aqueous solutions, or suspensions. Examplesof non-aqueous solvents are propylene glycol, polyethylene glycol, andinjectable organic esters such as ethyl oleate. Aqueous carriersinclude, for example, water, alcoholic/aqueous solutions, cyclodextrins,emulsions or suspensions, including saline and buffered media.

Parenteral vehicles (for subcutaneous, intravenous, intraarterial, orintramuscular injection) include, for example, sodium chloride solution,Ringer's dextrose, dextrose and sodium chloride, lactated Ringer's andfixed oils. Formulations suitable for parenteral administration include,for example, aqueous and non-aqueous, isotonic sterile injectionsolutions, which can contain anti-oxidants, buffers, bacteriostats, andsolutes that render the formulation isotonic with the blood of theintended recipient, and aqueous and non-aqueous sterile suspensions thatcan include suspending agents, solubilizers, thickening agents,stabilizers, and preservatives.

Intravenous vehicles include, for example, fluid and nutrientreplenishers, electrolyte replenishers such as those based on Ringer'sdextrose, and the like. Examples are sterile liquids such as water andoils, with or without the addition of a surfactant and otherpharmaceutically acceptable adjuvants. In general, water, saline,aqueous dextrose and related sugar solutions, and glycols such aspropylene glycols or polyethylene glycol are preferred liquid carriers,particularly for injectable solutions.

The choice of carrier will be determined, in part, by the particularSNAPP composition, as well as by the particular method used toadminister the composition. Accordingly, there are a variety of suitableformulations of the pharmaceutical SNAPP composition of the invention.The following formulations for parenteral, subcutaneous, intravenous,intramuscular, intraarterial, intrathecal and interperitonealadministration are exemplary, and are in no way limiting. More than oneroute can be used to administer the compositions of the presentinvention, and in certain instances, a particular route can provide amore immediate and more effective response than another route.

Injectable formulations are in accordance with the invention. Therequirements for effective pharmaceutical carriers for injectablecompositions are well-known to those of ordinary skill in the art (see,e.g., Pharmaceutics and Pharmacy Practice, J.B. Lippincott Company,Philadelphia, Pa., Banker and Chalmers, eds., pages 238-250 (1982), andASHP Handbook on Injectable Drugs, Trissel, 15th ed., pages 622-630(2009)).

For purposes of the invention, the amount or dose of the SNAPPs of thepresent invention that is administered should be sufficient toeffectively target the cell, or population of cells in vivo, such thatthe stimulation of the neuronal cells can be detected, in the subjectover a reasonable time frame. The dose will be determined by theefficacy of the particular SNAPP formulation and the location of thetarget population of neuronal cells in the subject, as well as the bodyweight of the subject to be treated.

The dose of the SNAPPs of the present invention also will be determinedby the existence, nature and extent of any adverse side effects thatmight accompany the administration of a particular SNAPP. Typically, anattending physician will decide the dosage of the SNAPPs with which totreat each individual subject, taking into consideration a variety offactors, such as age, body weight, general health, diet, sex, compoundto be administered, route of administration, and the severity of thecondition being treated. By way of example, and not intending to limitthe invention, the dose of the SNAPPs of the present invention can beabout 0.001 to about 1000 mg/kg body weight of the subject beingtreated, from about 0.01 to about 100 mg/kg body weight, from about 0.1mg/kg to about 10 mg/kg, and from about 0.5 mg to about 5 mg/kg bodyweight. In another embodiment, the dose of the SNAPPs of the presentinvention can be at a concentration from about 1 nM to about 10,000 nM,preferably from about 10 nM to about 5,000 nM, more preferably fromabout 100 nM to about 500 nM.

In accordance with another embodiment, the present invention provides amethod for identifying activated neurons in vitro comprising: a)providing a plurality of in vitro cultures comprising a plurality ofneurons in a growth medium; b) stimulating at least one or more of thecultures with a stimulant; c) removing the growth medium of theplurality of in vitro cultures; d) fixing the plurality of in vitrocultures; e) staining the plurality of in vitro cultures with at leastone or more SNAPP compositions as described herein; 0 quantifying thedetectable moiety of the compositions of e) using imaging and/orradiography; g) identifying the activated neurons as those neurons fromstimulated in vitro cultures which have a significantly increased amountof detectable signal from the detectable moiety compared to the amountof detectable signal in neurons from in vitro cultures which were notstimulated.

In accordance with a further embodiment, the present invention providesa method for screening for compounds which stimulate NMP and subsequentproduction of secreted cortical neuronal-activity induced proteasomalpeptides (SNAPPs) comprising the steps of: a) administering to a subjecta test compound for a period of time sufficient to stimulate NMP andallow production of SNAPPs in the neurons of the subject; b) providing anegative control by administering to at least a second subject for aperiod of time sufficient with a carrier or vehicle which will notstimulate NMP mediated production of SNAPPs in the neurons of the secondsubject; c) obtaining a biological sample from a) and b) and performingan isolation step to purify the SNAPPs from the biological samples of b)and c); d) quantifying the amount of SNAPPs isolated in e) from thebiological samples of a) and b); and e) determining that the testcompound is a stimulator of NMP mediated SNAPP production when thequantity of SNAPPs isolated from the biological samples of a) aresignificantly increased when compared with the amount of SNAPPs isolatedfrom the biological samples of b).

In accordance with another embodiment, the present invention provides amethod for screening for compounds which inhibit NMP mediated productionof secreted neuronal-activity induced proteasomal peptides (SNAPPs) in asubject comprising the steps of: a) administering to a first subject atest compound thought to be an inhibitor of NMP for a period of timesufficient to allow NMP mediated production of SNAPPs in the subject; b)providing a negative control by administering to at least a secondsubject for a period of time sufficient with a carrier or vehicle whichwill not stimulate NMP and secretion of SNAPPs in the second subject; c)providing a positive control by administering to at least a thirdsubject for a period of time sufficient with a known neuronal stimulantto allow NMP mediated production of SNAPPs in the subject; d) obtainingbiological samples from the subjects of a) to c) and performing anisolation step to purify the SNAPPs from the biological samples of a) toc); e) quantifying the amount of SNAPPs isolated in d) from thebiological samples of a) to c); and f) determining that the testcompound is an inhibitor of NMP mediated SNAPP production when thequantity of SNAPPs isolated from the biological samples of a) aresignificantly reduced when compared with the amount of SNAPPs isolatedfrom the biological samples of b) and/or c).

In accordance with another embodiment, the present invention provides amethod for identifying activated neurons in vivo comprising: a)administering to the neuronal tissue of a mammal an effective amount ofat least one or more SNAPP compositions as described herein, wherein theimaging agent is a SPECT or PET, or magnetic resonance imaging agent; b)imaging the neuronal tissue of the mammal; and c) identifying theactivated neurons as those neurons which have a significantly increasedamount of detectable signal from the detectable moiety compared to theamount of detectable signal from other neurons in the tissue.

In some embodiments the present invention employs an electromagneticradiation (emr) source for uniformly illuminating an area of neurons ofinterest, and an optical detector capable of detecting and acquiringdata relating to one or more optical properties of an area of interest.In a simple form, the apparatus of the present invention may include anoptical fiber operably connected to an emr source that illuminatestissue or neuronal cultures in vitro, and another optical fiber operablyconnected to an optical detector, such as a photodiode, that detects oneor more optical properties of the illuminated tissue. The detector isused to obtain control data representing the “normal” or “background”optical properties of an area of interest, and then to obtain subsequentdata representing the optical properties of an area of interest duringneuronal activity, e.g., stimulation of neuronal tissue, or during amonitoring interval. The subsequent data is compared to the control datato identify changes in optical properties representative of neuronalactivity. According to a preferred embodiment, the control, subsequentand comparison data are presented in a visual format as images.

In some embodiments, the present invention provides methods foroptically imaging neuronal tissue and the physiological eventsassociated with neuronal activity. The methods of the present inventionmay be used for optically imaging and mapping functional neuronalactivity, differentiating neuronal tissue from non-neuronal tissue,identifying and spatially locating dysfunctional neuronal tissue, andmonitoring neuronal tissue to assess viability, function and the like.

Numerous devices for acquiring, processing and displaying datarepresentative of one or more optical properties of an area of interestcan be employed. One preferred device is a video camera that acquirescontrol and subsequent images of an area of interest that can becompared to identify areas of neuronal activity or dysfunction.Examination of images provides precise spatial location of areas ofneuronal activity or dysfunction. Apparatus suitable for obtaining suchimages have been described in the patents incorporated herein byreference and are more fully described below. For most surgical anddiagnostic uses, the optical detector preferably provides images havinga high degree of spatial resolution at a magnification sufficient todetect single neuronal cells or nerve fiber bundles. Several images arepreferably acquired over a predetermined time period and combined, suchas by averaging, to provide control and subsequent images forcomparison.

In some embodiments the video camera is a Charge Coupled Device (CCD). ACCD is a type of optical detector that utilizes a photo-sensitivesilicon chip in place of a pickup tube in a video camera.

Various data processing techniques may be advantageously used to assessthe data collected in accordance with the present invention. Comparisondata may be assessed or presented in a variety of formats. Processingmay include averaging or otherwise combining a plurality of data sets toproduce control, subsequent or comparison data sets. Images arepreferably converted from an analog to a digital form for processing,and back to an analog form for display.

Data processing may also include amplification of certain signals orportions of a data set (e.g., areas of an image) to enhance the contrastseen in data set comparisons, and to thereby identify areas of neuronalactivity and/or dysfunction with a high degree of spatial resolution.For example, according to one embodiment, images are processed using atransformation in which image pixel brightness values are remapped tocover a broader dynamic range of values. A “low” value may be selectedand mapped to zero, with all pixel brightness values at or below the lowvalue set to zero, and a “high” value may be selected and mapped to aselected value, with all pixel brightness values at or above the highvalue mapped to the high value. Pixels having an intermediate brightnessvalue, representing the dynamic changes in brightness indicative ofneuronal activity, may be mapped to linearly or logarithmicallyincreasing brightness values. This type of processing manipulation isfrequently referred to as a “histogram stretch” and can be usedaccording to the present invention to enhance the contrast of data sets,such as images, representing changes in neuronal activity.

In accordance with another embodiment, the present invention provides amethod for making SNAPPs comprising the steps of: a) providing an invitro culture of a plurality of neurons in a growth medium; b)stimulating the neurons for a period of time sufficient to allowsecretion of SNAPPs into the growth medium; c) removing at least aportion of the growth medium containing the SNAPPs.

The term “neuron” is used herein to denote a cell that arises fromneuroepithelial cell precursors. Mature neurons (i.e., fullydifferentiated cells from an adult) display several specific antigenicmarkers.

The term “neuroepithelium” is used herein to denote cells and tissuesthat arise from the neural epithelium during development; such cellsinclude retinal cells, diencephalon cells and midbrain cells.Neuroepithelium is also defined as neuroectoderm, and more specificallyas ectoderm on the dorsal surface of the early vertebrate embryo thatgives rise to the cells (neurons and glia) of the nervous system.

As used herein, the term “neuron” means neuronal cells derived from thecentral nervous system of a subject, including, for example, the brain,spinal cord, as well as the peripheral nervous system, including, forexample, sensory and motor neurons. Areas of the brain where theseneurons can originate from include, but are not limited to, Cortex(Ctx), Hippocampus (Hip), Olfactory bulb (010, Hind Brain (Brn), forexample. Neurons can also be cells derived from induced pluripotent stemcell (iPSC) cultures.

The cell culture systems and methods used in the present invention maybe used in conjunction with any glass surface (including, for instance,coverslips) that has been coated with an attachment-enhancing substance,such as poly-lysine, Matrigel, laminin, polyornithine, gelatin and/orfibronectin. Feeder cell layers, such as glial feeder layers orembryonic fibroblast feeder layers, may also find use within the methodsand compositions provided herein.

Neuronal cells used in the present invention can be placed into anyknown culture medium capable of supporting cell growth, including MEM,DMEM, RPMI, F-12, and the like, containing supplements which arerequired for cellular metabolism such as glutamine and other aminoacids, vitamins, minerals and useful proteins such as transferrin andthe like. Medium may also contain antibiotics to prevent contaminationwith yeast, bacteria and fungi such as penicillin, streptomycin,gentamicin and the like. In some cases, the medium may contain serumderived from bovine, equine, chicken and the like. A particularlypreferable medium for cells is a mixture of Neurobasal and B-27 (catalog#21103049 and 17504044 respectively, Life Technologies, Gaithersburg,Md.).

Conditions for culturing should be close to physiological conditions.The pH of the culture media should be close to physiological pH,preferably between pH 6-8, more preferably close to pH 7, even moreparticularly about pH 7.4. Cells should be cultured at a temperatureclose to physiological temperature, preferably between 30° C.-40° C.,more preferably between 32° C.-38° C., and most preferably between 35°C.-37° C.

Neuronal cells can be grown in suspension or on a fixed substrate. Inthe case of propagating (or splitting) suspension cells, flasks areshaken well and the neurospheres allowed to settle on the bottom cornerof the flask. The spheres are then transferred to a 50 ml centrifugetube and centrifuged at low speed. The medium is aspirated, the cellsresuspended in a small amount of medium with growth factor, and thecells mechanically dissociated and resuspended in separate aliquots ofmedia.

Cell suspensions in culture medium are supplemented with any growthfactor which allows for the proliferation of progenitor cells and seededin any receptacle capable of sustaining cells, though as set out above,preferably in culture flasks or roller bottles. Cells typicallyproliferate within 3-4 days in a 37° C. incubator, and proliferation canbe reinitiated at any time after that by dissociation of the cells andresuspension in fresh medium containing growth factors.

As used herein, the term “stimulation” means the activation or firing ofthe neuron when the neuron is stimulated by pressure, heat, light, orchemical information from other cells. The type of stimulation necessaryto produce firing depends on the type of neuron. The cytosol inside aneuron is separated from that outside by a polarized cell membrane thatcontains electrically charged particles known as ions. When a neuron issufficiently stimulated to reach the neural threshold (a level ofstimulation below which the cell does not fire), depolarization, or achange in cell potential, occurs.

In accordance with some embodiments, neurons which produce SNAPPs can bestimulated by the use of a depolarizing buffer. Examples of such buffersinclude, but are not limited to physiological buffers containing highconcentration of KCl (60 mM to 150 mM or more), and can also includeadditional Ca⁺⁺ ions (10-20 mM). Other such depolarizing buffers includeglutamate or bicuculine and others.

Removal of cell growth medium from cell cultures which have beenstimulated can be performed using any known means in the art, e.g.,pipetting, filtration, etc.

In accordance with an embodiment, the present invention provides amethod for inhibiting NMP mediated production of SNAPPs in a neuronalcell or population of cells comprising contacting the cell or populationof cells with an effective amount of at least one proteasomal inhibitorfor a time sufficient to inhibit the NMP and production of SNAPPs.

In some embodiments, the proteasomal inhibitor can be one known in theart. For example, compounds such as Epoxomicin, biotin-Epoxomicin,Lactacystin, Bortezomib, MG-132, Carfilzomib, MLN9708, Ixazomib,PI-1840, ONX-0914, Oprozomib, CEP-18770, and Gabexate Mesylate are knownproteasomal inhibitors.

In accordance with a further embodiment, the present invention providesa method for screening for compounds which stimulate the NMP and thusproduction of secreted neuronal-activity induced proteasomal peptides(SNAPPs) comprising the steps of: a) providing a plurality of in vitrocultures comprising a plurality of neurons in a growth medium; b)providing one or more test cultures by contacting the neurons of atleast a first culture with a test compound for a period of timesufficient to inhibit the NMP and allow production of SNAPPs into thegrowth medium; c) providing a negative control by contacting the neuronsof at least a second culture for a period of time sufficient with acarrier or vehicle which will not stimulate NMP mediated production ofSNAPPs into the growth medium; d) removing at least a portion of thegrowth medium of the cultures of b) and c) and performing an isolationstep to purify the SNAPPs from the cultures of b) and c); e) quantifyingthe amount of SNAPPs isolated in e) from the cultures of b) and c); andf) determining that the test compound is a stimulator of SNAPP secretionwhen the quantity of SNAPPs isolated from b) are significantly increasedwhen compared with the amount of SNAPPs in c).

In accordance with yet another embodiment, the present inventionprovides a method for screening for compounds which inhibit the NMP andthus production of secreted neuronal-activity induced proteasomalpeptides (SNAPPs) comprising the steps of: a) providing a plurality ofin vitro cultures comprising a plurality of neurons in a growth medium;b) providing one or more test cultures by contacting the neurons of atleast a first culture with a test compound and with a known neuronalstimulant for a period of time sufficient to allow NMP mediatedproduction of SNAPPs into the growth medium; c) providing a negativecontrol by contacting the neurons of at least a second culture for aperiod of time sufficient with a carrier or vehicle which will notstimulate NMP mediated production of SNAPPs into the growth medium; d)providing a positive control by stimulating the neurons of a thirdculture for a period of time sufficient with a known neuronal stimulantto allow secretion of SNAPPs into the growth medium; e) removing atleast a portion of the growth medium of the cultures of b) to d) andperforming an isolation step to purify the SNAPPs from the cultures ofb) to d); f) quantifying the amount of SNAPPs isolated in e) from thecultures of b) to d); and g) determining that the test compound is aninhibitor of SNAPP secretion when the quantity of SNAPPs isolated fromb) are significantly reduced when compared with the amount of SNAPPs inc) and/or d).

The isolation and quantification of SNAPPs can be performed by variousmethods in the art. In some embodiments the SNAPPs can be isolatedvarious chromatographic methods, including, for example, UHPLCHydrophilic Interaction Chromatography (HILIC), normal phase, and/orreverse-phase C18 chromatography. These methods can be combined withultraviolet-visible (UV-vis) spectrophotometry, and other detectionmethods, to detect the SNAPPs eluting at various times off the differentcolumns.

In accordance with some embodiments, the sequences of SNAPPs can beidentified with many known methods. In an embodiment, advanced massspectrometric techniques after fractionation using matrix assisted laserdesorption/ionization after HPLC (LC-MALDI) or fractionation of an HPLCcolumn directly into an electrospray mass spectrometer (LC/MS-ESI) canbe used to identify the specific SNAPPs. Other methods, such as Edmandegradation and sequencing can be used.

Considering that many neurodegenerative disorders may result fromimproperly degraded proteins, we have tested whether the NMP is at alldysregulated in mouse models for neurodegeneration. Interestingly, inaccordance with some aspects of the present invention, the inventorsfound that the NMP is significantly perturbed rapidly in a disease modelof Alzheimer's and in human AD brains (FIG. 8) when compared to normalbrains.

As such, in accordance with an embodiment, the present inventionprovides a method for identifying a neuron or population of neurons ashaving aberrant or dysregulated NMP function comprising: a) providing atleast one first in vitro culture comprising a neuron or population ofneurons of interest; b) providing at least one second in vitro normal orcontrol cultures comprising a wild type or standard neuron or populationof neurons; c) contacting the neurons of the first and second culturedwith a stimulant compound for a period of time sufficient to allow NMPmediated production of SNAPPs into the growth medium; c) providing anegative control in vitro culture comprising a wild type or standardneuron or population of neurons by contacting the neurons of thenegative control for a period of time sufficient with a carrier orvehicle which will not stimulate secretion of SNAPPs into the growthmedium; d) removing at least a portion of the growth medium of thecultures of a) to c) and performing an isolation step to purify theSNAPPs from the cultures of a) to c); e) quantifying the amount ofSNAPPs isolated in e) from the cultures of a) to c); and f) determiningthat the first in vitro culture of interest has dysregulated NMPfunction when the quantity of SNAPPs isolated from a) are significantlyincreased or decreased when compared with the amount of SNAPPs in b).

In some embodiments, the above methods can be performed using cysteineor methionine amino acids labeled with ³⁵S added to the culture mediumprior to performing the methods of the present invention. Other labeledamino acids known in the art can also be used.

For example, the above methods can be used to compare the NMP functionof neurons having known neurodegenerative diseases or models for suchdiseases to normal neuronal function to determine which neurologicaldiseases or conditions are associated with dysregulated or aberrant NMPfunction.

In accordance with another embodiment, the present invention provides amethod for diagnosing a NMP associated disease or disorder of neuronalcells in a subject comprising: a) administering to the subject aneffective amount of a NMP stimulator or inhibitor to the subject; b)stimulating the neurons of interest; c) quantifying the amount of SNAPPsreleased after stimulation; d) comparing the amount of SNAPPs releasedin the subject to the amount released in normal control subjects; and e)identifying the subject as having a NMP associated disease or disorderof neuronal cells when the quantity of SNAPPs released in the subject inc) is significantly different than the quantity of SNAPPs released innormal control subjects.

Examples of proteasomal stimulators useful in the inventive methods caninclude, but are not limited to, PA28, PA200, PA700, arginine-richhistone H3), small molecules (oleuropein, betulinic acid—andderivtives), lipid activators (lysophosphatidylinositol, cardiolipin,ceramides), fatty acids (linoleic, oleic, linolenic acids), syntheticpeptidyl alcholos (pnitroanilides, nitriles). (Curr Med Chem. 2009;16(8):931-939).

As seen in FIG. 7, it is thought that certain neurological diseases canbe caused in whole or in part, by dysregulation of the NMP in theneuronal cells. Certain disorders may in fact, be caused by disruptionof NMP function or under expression of NMP proteins, causing an decreasein SNAPP production which may cause under stimulation of neural pathwaysdownstream from the affected cells. Conversely, certain disorders may infact, be caused by an excess of NMP function or over expression of NMPproteins, causing an increase in SNAPP production which may cause overstimulation of neural pathways downstream from the affected cells, andwhich may lead to neuronal apoptosis and death. Examples of degenerativediseases of the nervous system and brain which may be affected bychanges in NMP function or levels of expression or signaling include,but are not limited to psychiatric disorders, epilepsy, multiplesclerosis, autism, Alzheimer's disease, Parkinson's disease, amyotrophiclateral sclerosis, Huntington's, aging, dementia, enhancement learningand memory and other neurodegenerative diseases.

In accordance with an embodiment, the present invention provides Amethod for identifying a human subject as having a NMP associateddisease or disorder of neuronal cells comprising: a) obtaining abiological sample from said human subject; b) quantifying the amount ofSNAPPs in the sample from a); c) comparing the amount of SNAPPs in thesample from a) to the amount of SNAPPs in samples from normal controlsubjects; and d) identifying the subject as having a NMP associateddisease or disorder of neuronal cells when the quantity of SNAPPs in thesample from a) is significantly different than the quantity of SNAPPs insamples from normal control subjects. It will be understood by those ofordinary skill in the art that the quantification of SNAPPs in thesample can be performed using known methods, including, for example,those described here.

As used herein, the term “sample” or “biological sample” means samplesthat may be derived from bodily fluids, including, for example, one ormore selected from blood, serum, plasma, lymph, cerebrospinal fluid(CSF), tears, urine, amniotic fluid, and saliva of the subject beingtested, as well as purified extracellular vesicles (EVs) and inducedpluripotent stem cells.

In some embodiments, the NMP stimulators or inhibitors are combined witha pharmaceutically acceptable carrier as described herein. Moreover, theproteasomal stimulators or inhibitors can be combined with otherbiologically active agents.

An active agent and a biologically active agent are used interchangeablyherein to refer to a chemical or biological compound that induces adesired pharmacological and/or physiological effect, wherein the effectmay be prophylactic or therapeutic. The terms also encompasspharmaceutically acceptable, pharmacologically active derivatives ofthose active agents specifically mentioned herein, including, but notlimited to, salts, esters, amides, prodrugs, active metabolites, analogsand the like. When the terms “active agent,” “pharmacologically activeagent” and “drug” are used, then, it is to be understood that theinvention includes the active agent per se as well as pharmaceuticallyacceptable, pharmacologically active salts, esters, amides, prodrugs,metabolites, analogs etc. The active agent can be a biological entity,such as a virus or cell, whether naturally occurring or manipulated,such as transformed.

The biologically active agent may vary widely with the intended purposefor the composition. The term active is art-recognized and refers to anymoiety that is a biologically, physiologically, or pharmacologicallyactive substance that acts locally or systemically in a subject.Examples of biologically active agents, that may be referred to as“drugs”, are described in well-known literature references such as theMerck Index, the Physicians' Desk Reference, and The PharmacologicalBasis of Therapeutics, and they include, without limitation,medicaments; vitamins; mineral supplements; substances used for thetreatment, prevention, diagnosis, cure or mitigation of a disease orillness; substances which affect the structure or function of the body;or pro-drugs, which become biologically active or more active after theyhave been placed in a physiological environment. Various forms of abiologically active agent may be used which are capable of beingreleased the subject composition, for example, into adjacent tissues orfluids upon administration to a subject.

Examples of active agents that can be used with, or conjugated to theinventive SNAPPs, and NMP stimulators or inhibitors, and methodsinclude, but are not limited to autonomic agents, such asanticholinergics, antimuscarinic anticholinergics, ergot alkaloids,parasympathomimetics, cholinergic agonist parasympathomimetics,cholinesterase inhibitor parasympathomimetics, sympatholytics, α-blockersympatholytics, sympatholytics, sympathomimetics, and adrenergic agonistsympathomimetics, anesthetics, such as inhalation anesthetics,halogenated inhalation anesthetics, intravenous anesthetics, barbiturateintravenous anesthetics, benzodiazepine intravenous anesthetics, andopiate agonist intravenous anesthetics, skeletal muscle relaxants,neuromuscular blocker skeletal muscle relaxants, and reverseneuromuscular blocker skeletal muscle relaxants; neurological agents,such as anticonvulsants, barbiturate anticonvulsants, benzodiazepineanticonvulsants, anti-migraine agents, anti-parkinsonian agents,anti-vertigo agents, opiate agonists, and opiate antagonists,psychotropic agents, such as antidepressants, heterocyclicantidepressants, monoamine oxidase inhibitors selective serotoninre-uptake inhibitors tricyclic antidepressants, antimanics,anti-psychotics, phenothiazine antipsychotics, anxiolytics, sedatives,and hypnotics, barbiturate sedatives and hypnotics, benzodiazepineanxiolytics, sedatives, and hypnotics, and psychostimulants.

In another embodiment, the term “administering” means that at least oneor more SNAPPs or NMP stimulators or inhibitors of the present inventionare introduced into a subject, preferably a subject receiving treatmentfor a disease, and the at least one or more SNAPPs or NMP stimulators orinhibitors are allowed to come in contact with the one or more diseaserelated cells or population of cells in vivo.

As used herein, the term “treat,” as well as words stemming therefrom,includes diagnostic and preventative as well as disorder remitativetreatment.

As used herein, the term “subject” refers to any mammal, including, butnot limited to, mammals of the order Rodentia, such as mice andhamsters, and mammals of the order Logomorpha, such as rabbits. It ispreferred that the mammals are from the order Carnivora, includingFelines (cats) and Canines (dogs). It is more preferred that the mammalsare from the order Artiodactyla, including Bovines (cows) and Swines(pigs) or of the order Perssodactyla, including Equines (horses). It ismost preferred that the mammals are of the order Primates, Ceboids, orSimoids (monkeys) or of the order Anthropoids (humans and apes). Anespecially preferred mammal is the human. Moreover, the term “subject”includes tissues from deceased or fixed tissue.

EXAMPLES

Antibodies.

The following antibodies are commercially available and were usedaccording to manufacturer's suggestions for western blotting andimmunocytochemistry: anti-pCreb (Cell Signaling), anti-α1-7 proteasomesubunit (Santa Cruz), anti-α5 proteasome subunit (Santa Cruz), anti-β1proteasome subunit (Santa Cruz), anti-β2,5 subunit (Abcam), anti-β2proteasome subunit (Santa Cruz), anti-Rpt5 proteasome subunit (Enzo LifeSciences), anti-calregulin (Santa Cruz), anti-S6 (Cell Signaling),anti-CamKII (Cell Signaling), anti-pCamkll (Cell Signaling),anti-β-Actin (Abcam), anti-pErk (Cell Signaling), anti-Biotin (CellSignaling), anti-Streptavidin-647 (Invitrogen), anti-MAP2 (NeuroMab),anti-Tubulin (Cell Signaling), anti-GluR1 (Cell Signaling).

Mice.

All animal procedures were performed under protocols compliant andapproved by the Institutional Animal Care and Use Committees of TheJohns Hopkins University School of Medicine. Wild type C57Bl/6 mice wereobtained from Charles River laboratories (stock number 027).

Mouse cortical and hippocampal neurons were prepared from E16 C57Bl/6mouse embryos as previously described (Cell 143: 442-455 (2010)).Hippocampal neurons were maintained in Neurobasal Medium (Invitrogen)supplemented with 2% B27 (Invitrogen), penicillin/streptomycin (100 U/mLand 100 μg/mL, respectively), and 2 mM glutamine. Dissociated neuronswere transfected using the Lipofectamine method (Invitrogen) accordingto the manufacturer's suggestions.

Cell Culture.

HEK293T and Neuro2A cells were cultured in DMEM supplemented with 10%fetal bovine serum, 2 mM glutamine (Sigma), and penicillin/streptomycin(100 U/mL and 100 μg/mL, respectively; Sigma). Mouse cortical andhippocampal neurons were prepared from E17.5 C57Bl/6 mouse embryos aspreviously described (Cell 143, 442-455 2010). Neurons were maintainedin Neurobasal Medium (Invitrogen) supplemented with 2% B-27(Invitrogen), penicillin/streptomycin (100 U/mL and 100 μg/mL,respectively), and 2 mM glutamine. Dissociated neurons were transfectedusing the Lipofectamine method (Invitrogen) according to themanufacturer's suggestions.

Pulse-Chase Labeling.

Cortical neurons were cultured for 12-18 days in vitro. Neurons weremembrane depolarized with 55 mM extracellular KCl by addition ofprewarmed depolarization buffer (55 mM KCl, 0.2 mM CaCl₂, 1 mM MgCl₂, 10mM HEPES pH7.5) or a mock buffer (55 mM NaCl, final) in fresh neuronalgrowth media as previously described (Nature 455: 1198-1204 (2008)).Labeling was done in Neurobasal growth media with B27 supplement andwithout methionine or cysteine (Life Technologies, special order). ³⁵Smethionine-cysteine (EasyTag PerkinElmer) was incorporated at 55 mCi inthe cys/met free growth medium. Where indicated, MG132 (25 mM, CellSignaling) and ATPγS (1 mM, Sigma) was added during the radioactivelabeling window, 15 minutes prior to stimulation and was kept in for theduration of the stimulation.

For any chase experiment, free radioactivity was washed out withphosphate-buffered saline and replaced with fresh neuronal growthmedium. Time points were taken by removing medium and immediately lysingin RIPA buffer (50 mM Tris pH 8.0, 150 mM NaCl, 1% Triton X-100, 0.5%Sodium Deoxycholate, 0.1% SDS, 5 mM EDTA, 10 mM NaF, complete proteaseinhibitor cocktail tablet (Roche), 1 mM sodium orthovanadate, 1 mM(3-glycerophosphate). SDS sample buffer was added and samples wereboiled for 5 minutes prior to loading onto SDS-PAGE gels.

Surface biotin-labeling, cell lysis, streptavidin pulldown, proteasomepurification, and western blots.

Surface biotin-labeling was performed as previously described (NatNeurosci 12, 879-887 2009). Whole mouse brains, cultured cells or wholeanimal tissue were obtained where indicated and each sample was labeledusing Sulfo-NHS-LC-Biotin (ThermoFisher). Cultured cells were washed inpH 8.0 PBS (Gibco) with 1 mM CaCl₂ and 2 mM MgCl₂ (PBSCM) and treatedwith 1 mg/mL Sulfo-NHS-LC-Biotin dissolved in PBSCM for 20 minutes at 4°C. before the reaction was quenched for 10 minutes in 50 mM glycine inPBSCM. Intact tissue was quickly and manually chopped, followingbiotinylation for only 10 minutes at 4° C. in 0.5 mg/mLSulfo-NHS-LC-Biotin prior to quenching the reaction.

Whole mouse tissues and cultured neurons were collected and homogenizedin RIPA buffer (50 mM Tris pH 8.0, 150 mM NaCl, 1% Triton X-100, 0.5%Sodium Deoxycholate, 0.1% SDS, 5 mM EDTA, complete protease inhibitorcocktail tablet (Roche), 1 mM β-glycerophosphate).

Primary, human central nervous system (CNS) tissue, gestational weeks19-21, were obtained under surgical written consent following protocolsapproved by the Johns Hopkins Institutional Review Board, based on itsdesignation as biological waste. Tissue was mechanically chopped at 4°C., and immediately processed for surface biotinylation. Forstreptavidin pulldown experiments lysed cells were incubated with highcapacity streptavidin agarose beads overnight and then washed thricewith RIPA buffer before resuspension in SDS sample buffer.

For proteasome purification, cells were treated and then immediately puton ice before purifications were performed as previously described(Biochemistry 48: 2538-2549 (2009)). Briefly, supernatants wereincubated with GST-Ubl (1-3 mg) or 20S purification antibody Kit (Enzo)for 2 hours at 4° C., followed for 1 hour, and washed three times withice-cold RIPA buffer.

For western blots, samples were boiled for 5 minutes in SDS samplebuffer, resolved by SDS PAGE, transferred to nitrocellulose, andimmunoblotted. For time course studies, cortical neurons were biotinlabeled and homogenized for western analysis as described above. Forexperiments in HEK293T and Neuro2A cells, samples were boiled for 10minutes in 1% SDS buffer and diluted 1:5 in 1.25×RIPA buffer prior toloading on gel.

In some embodiments, proteasome purification was performed as follows.Cells were treated and then immediately put on ice before purificationswere performed as previously described (Methods Mol Biol 832, 423-432,2012). Briefly, proteasomes were purified out of neuronal cytosol anddetergent-extracted neuronal plasma membranes using the 20S proteasomepurification kit (Enzo Life Sciences) or the 26S proteasome purificationkit (UBPBio). For western blots, samples were denatured at 65° C. for 5minutes in SDS sample buffer, resolved by SDS PAGE, transferred tonitrocellulose, and immunoblotted. For catalytic activity assays, ⅙th ofthe bead volume following proteasome purification was resuspended inactivity assay buffer (20 mM Tris-HCl, pH8.0, 5 mM ATP, 5 mM MgCl₂, 1 mMDTT). 26S proteasomal activity was assessed by the addition of 10 μM ofSUC-LLVY-AMC (Enzo Life Sciences). The contribution of 20S proteasomalactivity was assessed by the comparison of 26S proteasome activity tothat of total proteasome activity (26S+20S), measured by the activity ofsamples containing SDS at a final concentration of 0.05%.

Immunocytochemistry.

Neurons were fixed for 5 minutes at 25° C. with 4% paraformaldehyde/4%sucrose in PBS For SNAPP imaging, fixed neurons were incubated withChicken anti-MAP2 antibodies (1:2000 each) and Goat anti-β2,5 proteasomesubunit antibodies (1:500) in 1× permeabilizing GDB (30 mM phosphatebuffer pH 7.4 containing 0.2% gelatin, 0.2% Saponin, and 0.8 M NaCl) or1× non-permeabilizing GDB (30 mM phosphate buffer pH 7.4 containing 0.2%gelatin, and 0.8 M NaCl) overnight at 4° C. Donkey anti-goat AF-555 anddonkey anti-chicken AF-488 (1:500 each in 1×GDB for 1 hour at 25° C.)antibodies were used to visualize the primary antibodies. Samples oncoverslips were mounted on glass slides using Fluoromount-G (SouthernBiotech). Neurons were imaged using a laser scanning Zeiss LSM710microscope. Images are representative maximal Z projections of multipleoptical sections.

For protein proteasome imaging experiments fixed neurons were similarlytreated using α-β2,5 subunit antibodies raised in goat (1:200). Sampleson coverslips were mounted on glass slides using Fluoromount-G (SouthernBiotech). Neurons were imaged using a laser scanning Zeiss Pascalmicroscope.

Immuno-Electron Microscopy and Analysis.

Cells were fixed in 1.5% glutaraldehyde (EM grade, Pella) buffered with70 mM sodium cacodylate containing 3 mM MgCl₂ (356 mOsmols pH 7.2), for1 hour at room temperature. Following a 30 minute buffer rinse (100 mMcacodylate 3% sucrose 3 mM MgCl₂, 316 mOsmols, pH 7.2), samples werepost-fixed in 1.5% potassium ferrocyanide reduced 1% osmium tetroxide in100 mM cacodylate containing 3 mM MgCl₂, for 1 hr in the dark at 4 C.After en-bloc staining with filtered 0.5% uranyl acetate (aq.), neuronswere dehydrated through graded series of ethanols and embedded/curedwith Eponate 12 (Pella). A metal hole punch was used to remove 5 mmdiscs from the polymerized plates. Discs were mounted onto epon blanksand trimmed. Sections were cut on a Reichert Ultra cut E with a Diatomediamond knife. 80 nm sections were picked up on formvar coated 200 meshnickel grids and treated for antigen removal followed by on gridimmunolabelling. Grids were floated on 95° C. citrate buffer pH 6.0 in aporcelain staining dish for 25 minutes, and then allowed to cool on thesame solution for 20 min. After a brief series of 50 mM TBS rinses,grids were floated on 50 mM NH₄Cl in TBS, blocked with 2% horse serum inTBS (no tween) for 20 minutes. Grids were incubated in primary antibodydiluted in blocking solution (1-50 Goat antibody). Grids incubated in1-50 Anti-biotin were diluted in 2% normal goat serum, overnight at 4°C. Grids incubated on blocking solutions served as negative controls.Sections were allowed to come to room temperature (1 hour) on antibodysolutions and placed on appropriated blocking solutions for 10 min.After further TBS rinses, grids were floated upon 12 nm Au conjugateddonkey anti-goat or 12 nm Au conjugated goat anti-rabbit (JacksonImmunoresearch) at 1-40 dilutions in TBS for 2 hours at roomtemperature. Grids were then rinsed in TBS, floated upon 1%glutaraldehyde for 5 min, rinsed again and stained with 2% filtereduranyl acetate. All grids were viewed with a Phillips CM 120 TEMoperating at 80 Kv and images were captured with an XR 80-8 MegapixelCCD camera by AMT.

Cellular Fractionation.

For fractionation experiments, linear sucrose gradients ranging from4-20% sucrose were made by layering equal volumes of 15% and 45% sucrosewith protease inhibitor in an ultracentrifuge tube and then using aGradientMaster (Biocomp) to linearize the sucrose gradient. Four platesof neurons stimulated, Cycloheximide (5 mM) was briefly added to stoptranslation, and neurons were rapidly lysed in a sucrose buffer (0.32 Msucrose, 5 mM HEPES, 0.1 mM EDTA, 25 mM DTT) following stimulation, andlayered over the sucrose gradient. Samples were subjected to high-speedultracentrifugation at 40000 RPM for 2 hours. 500 ul fractions weretaken and analyzed by SDS-PAGE and western blotting.

For cellular fractionation experiments to determine the membraneattachment of the proteasome, cultured neurons were lysed in either asucrose buffer (0.32 M sucrose, 5 mM HEPES, 0.1 mM EDTA, 0.25 mM DTT) orhypotonic lysis buffer (5 mM HEPES, 2 mM ATP, 1 mM MgCl₂) collected.Nuclei were pelleted at 800 RPM for 5 minutes, and the supernatantcontaining plasma membranes was pelleted at 55,000 RPM for 1 hour. Oncethe supernatant (cytosolic fraction) was set aside, the pellet waswashed 2× with lysis buffer, and then resuspended in lysis buffer withindicated concentrations of detergent. Following a 15-minute incubationin the buffer, samples were spun down at 55,000 RPM for 1 hour. This wasrepeated for all indicated concentrations of detergent. Membraneassociation was determined by classic methods of sodium carbonateextraction. Briefly, purified neuronal plasma membranes were resuspendedin 50 mM sodium carbonate, pH 11 and incubated for 30 minutes at 4° C.to strip away membrane associated proteins. Membranes, along withintegral membrane proteins, were pelleted at 55000 RPM for 1 hour.Samples were subsequently prepared for SDS-PAGE analysis.

Mass Spectrometry.

Mass spectrometry for interacting partners of the proteasome and ofsurface proteins was done at the W.M. Keck Foundation BiotechnologyResource Laboratory at Yale University.

SNAPP Collection and Identification.

Following incorporation of radioactive ³⁵S methionine/cysteine, and 35minutes of stimulation in 10 cm² dishes, neurons were rapidly washed inPBS and fresh Neurobasal media without phenol red and with 2×B-27supplement was added. At the two-minute time point, all of the media wascollected and then spun through a 10 kDa Amicon filter (Millipore) andthe flow through was then spun through a 3 kDa Amicon filter(Millipore). The flow through from this sequential filtering was thendialyzed with dialysis tubing with a 100-500 Da cutoff (Spectrum Labs)into either 1×PBS (Gibco) or 20 mM NH₄HCO₃ (Sigma). Samples weredialyzed into PBS for the purposes of biotin-tagging and were dialyzedinto NH₄HCO₃ for both stimulation and for purification. Followingdialysis, samples were lyophilized and resuspended in MilliQ water fordownstream application.

Quantification of SNAPPs was done by quantifying the amount ofradioactivity in each sample by liquid scintillation (Wallac 1410). Todetermine the nature of SNAPPs, we first separated the SNAPPs by UHPLCon three different chromatography columns optimized for diverse compoundchemistries in order to have the broadest detection capabilities ofthese unknown peptides. Using ultraviolet-visible (UV-vis)spectrophotometry, we were able to detect an abundance of peptideseluting at various times off the different columns, suggesting thatSNAPPs contain peptides of varying sizes and hydrophobicity.

SNAPP Labeling and Imaging.

SNAPPs were collected, filtered, and dialyzed into PBS and then wereincubated with 1 mg/mL NHS-Biotin (ThermoFisher) overnight at 4° C. Thebiotin reaction was quenched with 30 mM glycine (Sigma) andbiotin-tagged SNAPPs were re-dialyzed to ensure that any unreactedbiotin was removed. Purified biotinylated SNAPPs were then used as areagent for subsequent imaging experiments at a 1:1 ratio(SNAPP-tags:GDB).

Biotin-Epoxomicin.

Biotin-epoxomicin is de-novo synthesized and purchased from LeidenUniversity Institute of Chemistry. Biotin-epoxomicin was added toneuronal cultures at 25 mM immediately after labeling. Preincubation wasnot necessary. Following SNAPP release assays, treated cells were lysedin a sucrose homogenization buffer (0.32M sucrose, 5 mM HEPES, 0.1 mMEDTA, 0.25 mM DTT). Membranes were separated from the cytosol byhigh-speed centrifugation at 55,000 RPM for 1 hour. Fractions weresolubilized in SDS sample buffer prior to loading on SDS-PAGE gels forwestern analysis. EM processing was done after 5 minutes of treatmentwith Biotin-Epoxomicin.

Calcium Imaging.

Calcium imaging was performed as previously described (Neuron 81,873-887, 2014). Briefly, for the Biotin-Epoxomicin experiments, culturedembryonic cortical neurons were transfected with 1 μg of a mammalianexpression construct encoding GCaMP3 at DIV10 and imaged at DIV 12-14.Bicuculline treatment was administered as a 1 μM stimulation in calciumimaging buffer in a perfusion setup. Once the bicuculline stimulationwas washed out, biotin-epoxomicin (25 μM) was co-administered with 1 μMBicuculline in calcium imaging buffer. Each treatment was monitored forthree minutes prior to washout. Coverslips were not imaged twice due toBiotin-Epoxomicin being a covalent inhibitor. Cells were ensured to behealthy at the end of the imaging process by stimulating with 55 mM KCland washing out and assessing for a proper calcium signal.Quantification was done by picking multiple regions of interests inprimary and secondary dendrites across multiple coverslips overdifferent imaging days. Data was analyzed using the Time Series AnalyzerV3.0 ImageJ plugin and the ROI manager. Data were pooled for all theROIs to generate a single N value. Brains from P0-P3 mouse pups (CreGCaMP3; Nestin-Cre ER) were dissected and plated in Neurobasal-A withB-27 supplement for two weeks. At DIV7, 4-hydroxytamoxifen (4-HT,concentration) was added to induce GCaMP expression. Neurons were imagedin a calcium-imaging buffer (130 mM NaCl, 3 mM KCl, 2.5 mM CaCl₂, 0.6 mMMgCl₂, 10 mM Hepes, 10 mM glucose, 1.2 mM NaHCO₃ pH 7.45). Peptides werecollected, filtered, and dialyzed and then lyophilized prior toresuspension in 1 mL of MilliQ water and addition onto GCaMP-encodingneurons. 5 μl of resuspended peptides were sufficient to induce thedescribed calcium-induced effects. Peptides treated with Proteinase Kwere spun through a 10 kDa MW cutoff filter prior to addition ontoneurons in order to remove Proteinase K. Random peptide mixturescontained HIV-TAT, a polybasic peptide mixture, or a crude peptide prep.

Human Brain Samples.

All human tissue handling was performed under protocols compliant andapproved by the The Johns Hopkins University School of Medicine.

Example 1

A catalytically active 20S proteasome is integral to neuronal plasmamembranes.

Previous studies attempting to ascribe proteasomes with distinctfunction in the nervous system have identified localization as a keyfeature of determining proteasome function. However, all of thesestudies have focused on the 26S proteasome, either through the use offluorescently-tagged cap subunits, or have used complex electronmicroscopy approaches to assess the distribution of 26S cappedproteasomes in neurons. Taking a more unbiased approach to evaluatelocalization of all proteasomes in the nervous system, the inventorsperformed an immunogold electron microscopy (Immuno-EM) analysis ofcortical neuronal cultures using an antibody that detects β2, a coreproteasomal subunit common to all catalytically active proteasomes.Since core proteasome subunits have never been shown to be separatedfrom the rest of the macromolecular proteasome complex, these datalikely reflected the localization of intact proteasome complexes. Whilewe observed diverse subcellular localization of β2-subunits in neuronalcells, as previously reported, we made the unexpected observation that42±3% of all gold particles localized to the neuronal plasma membrane(FIG. 1A). We did not see similar localization in heterologousnon-neuronal cells. Closer analyses of our Immuno-EM data revealedplasma membrane-localized β2-subunits as integral to plasma membranes(43±3%) and/or peripheral to membranes at the intracellular face (39±2%)(FIG. 1A). This localization suggested that proteasomes were interactingwith the plasma membrane, a surprising and never-before seen phenomenon.These data were corroborated by an orthogonal biochemical method thatdemonstrated that upon separating neuronal plasma membranes from thecytosol, a large fraction (40±2%) of another set of core proteasomesubunits, α₁₋₇, were localized to plasma membranes (FIG. 1B). To furthercharacterize the biochemical nature of proteasome-plasma membraneinteraction, we fractionated neuronal cultures into cytosolic,peripherally membrane-associated, and integral-membrane proteins.Immunoblotting these fractions showed that core 20S proteasomecomponents were, in fact, integral and not peripheral to plasmamembranes, whereas 26S cap components were primarily cytosolic (FIG.1C).

To assess whether the proteasome subunits we observed in the neuronalplasma membrane constituted intact 20S proteasomes, we attempted topurify proteasomes out of the plasma membrane using two differentaffinity methods. While both 20S and capped-26S affinity purificationmatrices were able to isolate proteasomes out of the cytosol, only the20S purification matrix was able to purify proteasomes out of membranes(FIG. 1D). These data indicated that a membrane complex made up of core20S proteasomal subunits is molecularly distinct from cytosolicproteasomes and can be purified together as a proteasome holocomplexthat may be functional. As such, we henceforth referred to this neuronalmembrane proteasome as the NMP.

To test whether the NMP was catalytically active, we purified NMPs fromneuronal plasma membranes using a 20S purification matrix and incubatedthem with nonlimiting concentration of a specific substrate thatfluoresces upon proteasomal chymotrypsin-like cleavage. We determined,in vitro, that the NMP retained a similar degree of catalytic activityto that of cytosolic proteasomes (FIG. 1E). Interestingly, the catalyticactivity of the NMP was potently stimulated by the presence of a lowconcentration of sodium-dodecyl-sulfate (SDS) (FIG. 1E), acharacteristic property of uncapped 20S proteasomes as SDS has beenshown to open the gating mechanism of the 20S proteasome withoutdenaturing the holocomplex.

These findings were highly intriguing; while proteasomes have beenproposed to interact with the ER membrane, no study has reportedproteasome subunits to localize at or be integral to plasma membranes.Considering that the plasma membrane is the site at which the neuroninterfaces with the extracellular environment and serves as a criticalsignaling hub, we hypothesized that the NMP may mediate rapidproteasome-dependent effects on neuronal signaling. However, from thedata thus far, it was unclear how the NMP could transduce signals fromthe neuron to the extracellular space, or vice versa. To interrogatethis possibility, we focused on another curious aspect of our Immuno-EMdata, which indicated that a significant fraction (18±2%) of proteasomesappeared surface-exposed (FIG. 1A).

Example 2

The NMP is exposed to the extracellular space, is specific to thenervous system, and is temporally regulated.

We postulated that a catalytically active proteasome with access to boththe intracellular and extracellular space would be positioned in such amanner to rapidly modulate neuronal function through its proteolyticactivity. Thus, to validate our Immuno-EM data, we proceeded with aseries of classic approaches to assay whether proteins are exposed tothe extracellular space (FIG. 2A). First, cortical neurons were fixedand stained using antibodies against catalytic proteasome subunits underboth permeabilizing and non-permeabilizing conditions. Consistent withthe NMP being surface exposed, we observed immunostaining againstproteasomal subunits under both conditions, but only observed cytosolicMAP2 staining under permeabilizing conditions (FIG. 2A). Tobiochemically determine whether the NMP was surface-exposed, we foundthat proteasome subunits in neuronal membranes were susceptible toproteolysis by extracellular application of the broad spectrum serineprotease, Proteinase K (PK), to cultured cortical neurons, whereascytosolic proteasome subunits were protected from protease cleavage(FIG. 2B). As an orthogonal method of identifying surface exposedproteins, we turned to previously describedsurface-biotinylation/purification approaches. Briefly, corticalneuronal cultures were treated with a cell-impermeable reactivebiotin-NHS-ester to exclusively and covalently label proteins thatcontained epitopes that were exposed to the extracellular space. Weconfirmed that a host of core 20S proteasome subunits could be isolatedfrom these surface-biotinylated neuronal lysates on streptavidin beads,providing further evidence that the NMP was exposed to the extracellularspace (FIG. 2C). We did not detect a key 26S cap protein Rpt5 orcontamination from abundant cytosolic proteins in oursurface-biotinylated pulldowns (FIG. 2C). Similar results were observedin human neurons, demonstrating the conservation of these findingsacross mammals (Figure S2A). Extending these findings in vivo, wedetermined that the expression of the surface-exposed NMP was unique toneuronal tissues as compared to five other major organs and heterologouscell lines (FIG. 2D, 2E).

Consistent with NMP expression being unique to the nervous system, wedetermined that NMP expression paralleled in vivo expression patterns ofGluR1, a neuronal-specific ionotropic receptor whose expressionfunctionally correlates with critical stages in neuronal development.Performing the same experiments in vitro, we observed that the NMP wasexpressed in neurons at 8 days in vitro (DIV), but not prior, indicatinga clear temporal shift in proteasome expression at the plasma membrane(FIG. 2F). These experiments demonstrated that our experimental approachto isolate surface-exposed proteasome components is not contaminated bycytosolic proteasome expression, as total proteasome expression isabundant in neurons younger than 8 DIV even though surface expression isabsent. Taking advantage of this temporal regulation of NMP expression,we used comparative liquid-chromatography/mass-spectrometry ofsurface-biotinylated samples from neurons at 8 DIV, compared to 7 DIV,to determine the complete composition of the NMP. This analysis revealedthe expected result that the NMP contained almost all core 20S subunits(FIG. 2G), thus indicating that the NMP was a complete 20S proteasomeintegral to plasma membranes and exposed to the extracellular space.

Our data suggested that the NMP was oriented in such a manner that itwould have access to both the intracellular and extracellular space topossibly perform some form of transmembrane signaling. It remained to bedetermined whether this form of signaling existed, how it wasmanifested, and what its function was.

Example 3

The NMP Mediates Degradation of Intracellular Proteins intoExtracellular Peptides

Given that it was catalytically active in vitro, we hypothesized that inintact cells, the NMP would promote proteasome-dependent degradation ofintracellular proteins into the extracellular space. To test ourhypothesis, we used 35S-radiolabelling approaches to trace the fate ofnewly synthesized intracellular proteins (Schubert et al., 2000).35S-methionine/cysteine was quickly incorporated into neurons; additionof proteasome inhibitors had no effect on radiolabeling efficiency (FIG.3A). After 10 minutes of radiolabeling, free radioactivity was washedaway, and media was collected over a time course and analyzed by liquidscintillation. We observed rapid proteasome-dependent release ofradioactivity into the culture medium. Of the released radioactivematerial, 90±3% was made up of Proteinase K-sensitive molecules thatranged between 500 and 3000 Daltons in size (FIG. 3B). From this, weconcluded that the radioactivity in the media was composed of proteinpeptides derived from the proteasome (Kisselev et al., 1998) and notindividual amino acids or small molecules. This is consistent with themodel that the NMP was degrading intracellular proteins intoextracellular peptides, since proteasome cleavage products are peptidesbetween 500 and 3000 Da in size. In further support of the NMP acting asa 20S proteasome complex, release of radioactive material into theextracellular space was not dependent on ATP hydrolysis, another keycharacteristic of functional 20S proteasomes (FIG. 3C). While these dataagreed with our hypothesis that the NMP is responsible for thistransmembrane degradation, our data thus far did not discriminatebetween cytosolic and membrane proteasomes. Taking advantage of thetemporal expression of the NMP between 7 DIV and 8 DIV, we observed thatproteasome-dependent release of radioactivity into the media paralleledthe temporal expression of the NMP (FIG. 3D). Again, this experimentalparadigm demonstrates that the release of radioactivity was bothregulated and dependent upon proteasome function. Moreover, we observedrelease of radioactivity in 8 DIV neurons compared to 7 DIV neurons,despite the presence of cytosolic proteasomes at both 7 DIV and 8 DIV.Therefore, these data suggested that the NMP may be responsible for thedirect conversion of intracellular proteins into extracellular peptides.

Example 4

Given the importance of proteasomes during neuronal stimulation, weconsidered that during neuronal activity proteins may be more rapidlyprocessed by the proteasome and the processed peptides were secretedfrom the neurons into the media. To test this idea, we quantified theradioactivity in the media following stimulation, and consistent withour hypothesis, we observe a stimulation-induced increase in theradioactivity in the media (FIG. 4A). In contrast, inhibition ofactivity dependent pathways blocked this release in neurons undergoingspontaneous activity. Based on the size and nature of these peptides, webelieve them to not contain any previously discovered neurotrophicfactors, which are larger than 3 kDa. In addition, the rapid timekinetics of peptide release and the fact that a majority of thesepeptides derive from the proteasome suggest that they are not in knownclasses of neuropeptides. Canonical neuropeptides require extensivemodifications and cleavage events that are inconsistent with our timekinetics; moreover, these cleavage events are not mediated by theproteasome and are not able to be inhibited by proteasome inhibitorssuch as MG-132. Intriguingly, the production and release of thesenon-canonical peptides seems to be restricted to the nervous system, asother cell types we have tested do not exhibit this phenomenon (data notshown). Given that these peptides represent novel peptides specific tothe nervous system related to aspects of neuronal activity we will referto these peptides as secreted neuronal-activity induced proteasomalpeptides or SNAPPs.

To determine the nature of these SNAPPs, we first separated the SNAPPsby UHPLC on three different chromatography columns optimized for diversecompound chemistries in order to have the broadest detectioncapabilities of these unknown peptides. Using ultraviolet-visible(UV-vis) spectrophotometry, we were able to detect an abundance ofpeptides eluting at various times off the different columns, suggestingthat SNAPPs contain peptides of varying sizes and hydrophobicity.Interestingly, biological replicates show similar SNAPP profilesindicating that the specific sequences generated may be regulated.

Considering SNAPPs were endogenous molecules being released from neuronsfollowing stimulation, we sought to determine their biologicalsignificance en masse. To test the biological significance of SNAPPs wepurified and added them onto naive cells to determine if they had anycapacity to induce neuronal signaling (FIG. 4B). Mice encoding aubiquitously expressed genetically encoded calcium indicator, GCaMP3,were sacrificed and cortices were dissected and cultured. GCaMP encodingneurons were perfused with SNAPPs for one minute, and then the peptideswere washed out. Calcium imaging over this time-course demonstrates thatSNAPPs induced calcium transients that were sustained for severalminutes even following removal of the SNAPPs from the perfusion (FIG.4C). In light of these data, we added these peptides onto DIV14 neuronsin culture and looked for stimulation of calcium-sensitive pathways.Consistent with the GCaMP imaging data, we demonstrate that thephospho-CaMKII and phospho-ERK pathways are both stimulated by SNAPPs,but not from material derived from proteinase K treated SNAPPs (FIG.4D). Moreover, growth factor induced pathways, such as TrkB signaling;do not respond to SNAPP addition, further demonstrating that SNAPPs donot contain known released growth factors (data not shown). Tounderstand further the mechanism by which SNAPPs were acting tostimulate the calcium sensitive pathways, we asked whether they werecapable of binding neurons. After isolating and purifying the SNAPPs, wetagged them with biotin, quenched the biotinylation reaction, and madesure to remove all excess biotin with dialysis. We then added thesebiotin tagged SNAPPs onto fixed cells to identify where they werebinding. Intriguingly, we observe that these peptides display anenhanced propensity for binding KCl stimulated neurons over unstimulatedneurons (FIG. 4E). This binding capacity is also proteinase K sensitive,further confirming that the binding is due to peptides (data not shown).Media derived from cells stimulated in the presence of proteasomeinhibitors does not display this ability to bind neurons, furthersuggesting that SNAPPs possess the unique capacity for this labeling.Using optogenetic approaches, we sought to determine the sensitivity ofthis SNAPPs tagging of activated neurons. Channelrhodopsin was sparselytransfected into neuronal culture, and the culture was light stimulatedand subsequently stained using SNAPPs. We demonstrate that thestimulated neuron and some neurons surrounding that neuron were marked,but neurons that were not adjacent to the Channelrhodopsin-encodingneuron were not marked using the SNAPPs (FIG. 4F). This was not observedfor Channelrhodopsin labeled neurons stimulated with ambient light (FIG.4F). These data indicate that SNAPPs are a diverse population ofactivity induced secreted signaling peptides capable of inducingneuronal activity and intriguingly, are able to selectively bindstimulated neurons.

Example 5

Developmentally regulated SNAPP release is tightly correlated with aproteasome expressed at the neuronal membrane.

As compared to DIV 8 and older neurons, DIV 7 neurons do not displaySNAPP release (FIGS. 5A and 5B). The developmental regulation of bothNMP (FIG. 2F) expression and the corresponding release of SNAPPs was thefirst piece of evidence that indicated to us that the NMP is responsiblefor SNAPP release.

Example 6

The NMP modulates neuronal activity through the production ofextracellular signaling peptides.

To specifically determine the contributions from the NMP in this processof proteasome-directed peptide signaling, separately from the cytosolicproteasome, we identified a chemical tool that was highly selective tothe NMP. We found that the addition of a biotin group on thenon-reactive portion of epoxomicin, a highly potent, specific, andcovalent inhibitor of catalytically active proteasomes generates a newcompound (biotin-epoxomicin) that is unable to cross neuronal cellmembranes, yet maintains target specificity. Biochemical fractionationof neurons treated with biotin-epoxomicin confirmed thatbiotin-epoxomicin is indeed membrane-impermeable (FIG. 5A). Furthermore,Immuno-EM analysis of cortical neuronal cultures treated withbiotin-epoxomicin showed 91±5% of biotin at plasma membranes (FIG. 5B).Any cytosolic labeling is likely due to the presence of endogenouslybiotinylated proteins, as we see cytosolic labeling in cultures treatedwith vehicle control, but an absence of labeling in our secondary-onlycontrols. These data independently confirmed that the membraneproteasome is catalytically active, since epoxomicin requires that theproteasome be active in order to covalently bind to and inhibit thecatalytic subunits. Using this inhibitor, we sought to separate the rolefor the NMP from the role of cytosolic proteasomes in regulatingextracellular peptide production. Application of biotin-epoxomicin toradiolabeled cortical neurons led to the acute inhibition of radioactivepeptide release into the extracellular space (FIG. 5C). Based on thesedata, we believe that the endogenous NMP is catalytically active,directly and specifically mediates the degradation of intracellularproteins into extracellular peptides, and that biotin-epoxomicin is auseful tool to study the relevance of the NMP. With this tool validated,we wanted to test our initial hypothesis that membrane-apposedproteasomes may play a role in rapid neuronal signaling.

To test whether the NMP was relevant to aspects of neuronal signaling,changes in intracellular calcium were measured since calcium serves as arapid readout for many types of neuronal signaling. Calcium imaging wasperformed using GCaMP3-transfected cultured cortical neurons treatedwith GABAergic receptor antagonist bicuculline, which relievesinhibition on neuronal circuits, inducing regular firing of actionpotentials and calcium transients. Addition of biotin-epoxomicinstrongly and rapidly attenuated the amplitude of bicuculline-inducedcalcium transients, similar to that which we observed upon acuteaddition of MG-132 (FIG. 5D). These data validated our initialhypothesis that membrane-apposition of proteasomes would render themcapable of rapidly affecting neuronal signaling. Based on these data, anendogenous function of the NMP is to modulate the strength and speed ofactivity-dependent neuronal signaling through its proteolytic activity,possibly through the actions of the resulting extracellular peptides.These data are consistent with the NMP producing extracellular peptidescapable of modulating neuronal signaling, that we found when titratedonto naïve GCaMP3-encoding neurons are sufficient to induce robustcalcium transients within 10 seconds of addition. These data signifythat the ability for purified media to stimulate calcium transients innaïve neurons relies upon NMP-mediated release of peptides into theextracellular space.

Example 7

NMP expression is conserved in Humans and varies across individuals.

Fetal human brains were obtained according to Institutional Review BoardProtocol. Fresh tissue was dissected and sliced and then surfacebiotinylated. Surface proteins were isolated on streptavidin beads andsubsequently analyzed by western blot. Proteasome subunits were pulleddown on streptavidin beads, whereas cytosolic protein actin was not. InFIG. 6, inputs are shown to the left of the streptavidin pulldown.Expression was found to be fairly consistent across humans, except forone sample that demonstrated much higher expression. Further analysisrevealed that the patient who consented for the procedure was on regularmethadone use for treatment of heroin addiction. These samples were runblinded. Densitometry quantification is shown to the right, withexpression of the NMP normalized to the total amount of proteasome.

Example 8

Dysregulation of the NMP in Alzheimer's Disease.

NMP expression was measured in mouse cortical neurons treated with avariety of compounds, including Aβ₁₋₄₂. DIV12 mouse neurons were treatedwith 1 μM Aβ₁₋₄₂ peptide for 12 hours. Following treatment, neurons weresurface biotinylated, and surface proteins were isolated and analyzed bywestern blot (FIG. 7). Inputs are shown to the left of the streptavidinpulldown. There was a significant decrease in expression of proteasomesubunits in the streptavidin pulldown from Aβ treated neurons.

Example 9

NMP expression in samples from post-mortem Human patients withAlzheimer's disease.

Primary samples from 10 patients were obtained from the Johns HopkinsLieber Institute for Brain Development Brain Bank. All tissue wasobtained under their IRB. Samples were blinded, and then surfacebiotinylated and lysed. Surface proteins were pulled down onstreptavidin beads and analyzed by western blot. Inputs are shown abovethe streptavidin pulldown (FIG. 9). Lower expression levels ofproteasome subunits were seen in 5 different samples, which wererevealed to be from patients who had Alzheimer's. Samples are labeledunderneath as either AD (+) for AD positive samples or AD (−) forunaffected individuals. This blinded approach confirms the ability touse NMP expression as a diagnostic method for Alzheimer's disease.Quantification is shown to the right, with the levels of the NMPnormalized against the total proteasome levels (FIG. 9). * P<0.01,Student's t-test, n=5.

Example 10

Dysregulation of the NMP in a Murine Model of Alzheimer's Disease.

Brains from early stage (3 month old) J20 AD mouse model (see FIG. 10)and wild type mice were treated as in FIG. 4C to isolate the NMP. Thisstage in development is fairly early in AD progression. Samples were runon SDS-PAGE and probed for proteasome, APP and actin. Note that in ADmouse models at early stages of disease progression we observe anincrease in NMP as opposed to a decrease when treating neurons inculture with Aβ or from late stage human AD samples. This indicates thatthe NMP is dynamic in nature during prior to and during AD progressionand can be specifically studied for its contribution to AD relatedphenotypes in these and other mouse models. The NMP is one of the fewproteins ever shown to have such a dramatic change in expression in thisAD model so early in development of the disease.

Example 11

Dysregulation of the NMP in a Murine Model of Huntington's Disease.

The striatum was dissected from 6 week aged Huntington transgenicanimals. This stage of development is fairly early in the diseaseprogression of Huntington in these animals, where few robust changeshave been detected at this early stage. Dissected tissue was surfacebiotinylated, and surface proteins were isolated on streptavidin beads.Inputs are shown above streptavidin pulldown (FIG. 11). A robustdecrease in the levels of the NMP in Huntington positive (+) striatum isshown, and quantified to the right as normalized to input proteasomelevels. These data suggest that the NMP may be an early diagnostic inthe progression of Huntington's disease.

All references, including publications, patent applications, andpatents, cited herein are hereby incorporated by reference to the sameextent as if each reference were individually and specifically indicatedto be incorporated by reference and were set forth in its entiretyherein.

The use of the terms “a” and “an” and “the” and similar referents in thecontext of describing the invention (especially in the context of thefollowing claims) are to be construed to cover both the singular and theplural, unless otherwise indicated herein or clearly contradicted bycontext. The terms “comprising,” “having,” “including,” and “containing”are to be construed as open-ended terms (i.e., meaning “including, butnot limited to,”) unless otherwise noted. Recitation of ranges of valuesherein are merely intended to serve as a shorthand method of referringindividually to each separate value falling within the range, unlessotherwise indicated herein, and each separate value is incorporated intothe specification as if it were individually recited herein. All methodsdescribed herein can be performed in any suitable order unless otherwiseindicated herein or otherwise clearly contradicted by context. The useof any and all examples, or exemplary language (e.g., “such as”)provided herein, is intended merely to better illuminate the inventionand does not pose a limitation on the scope of the invention unlessotherwise claimed. No language in the specification should be construedas indicating any non-claimed element as essential to the practice ofthe invention.

Preferred embodiments of this invention are described herein, includingthe best mode known to the inventors for carrying out the invention.Variations of those preferred embodiments may become apparent to thoseof ordinary skill in the art upon reading the foregoing description. Theinventors expect skilled artisans to employ such variations asappropriate, and the inventors intend for the invention to be practicedotherwise than as specifically described herein. Accordingly, thisinvention includes all modifications and equivalents of the subjectmatter recited in the claims appended hereto as permitted by applicablelaw. Moreover, any combination of the above-described elements in allpossible variations thereof is encompassed by the invention unlessotherwise indicated herein or otherwise clearly contradicted by context.

1. A method for identifying a NMP associated disease or disorder in a sample of neuronal cells comprising: a) isolating the surface proteins of the neuronal tissue; b) analyzing the surface proteins of a) for the quantity of expression of one or more 20S protein core subunit proteins; c) providing a reference neuronal tissue sample; d) comparing the quantity of expression of one or more 20S protein core subunit proteins from the sample of a) to the quantity of expression of one or more 20S protein core subunit proteins from the reference sample; and e) identifying the neurons in the sample as having a NMP associated disease or disorder of neuronal cells when the quantity of expression of one or more 20S protein core subunit proteins from the cortical neuronal tissue sample is significantly greater or less than the quantity of expression of one or more 20S protein core subunit proteins from the reference sample.
 2. The method of claim 1, wherein the neuronal tissue is derived from the central nervous system or peripheral nervous system of the subject.
 3. The method of claim 1, wherein the disease is selected from the group consisting of wherein NMP associated disease or disorder of neuronal cells is selected from the group consisting of psychiatric disorders, epilepsy, multiple sclerosis, autism, Alzheimer's disease, Parkinson's disease, amyotrophic lateral sclerosis, Huntington's, aging, dementia, enhancement learning and memory and other neurodegenerative diseases. 4.-11. (canceled)
 12. A method for screening for compounds which stimulate secretion of NMP mediated production of neuronal-activity induced proteasomal peptides (SNAPPs) comprising the steps of: a) providing a plurality of in vitro cultures comprising a plurality of neurons in a growth medium; b) providing one or more test cultures by contacting the neurons of at least a first culture with a test compound for a period of time sufficient to allow NMP mediated production of SNAPPs into the growth medium; c) providing a negative control by contacting the neurons of at least a second culture for a period of time sufficient with a carrier or vehicle which will not stimulate NMP mediated production of SNAPPs into the growth medium; d) removing at least a portion of the growth medium of the cultures of b) and c) and performing an isolation step to purify the SNAPPs from the cultures of b) and c); e) quantifying the amount of SNAPPs isolated in e) from the cultures of b) and c); and f) determining that the test compound is a stimulator of NMP and SNAPP production when the quantity of SNAPPs isolated from b) are significantly increased when compared with the amount of SNAPPs in c).
 13. The method of claim 12, further comprising the steps of: c1) providing a positive control by stimulating the neurons of a first culture for a period of time sufficient with a known neuronal stimulant to allow NMP mediated production of SNAPPs into the growth medium; d1) removing at least a portion of the growth medium of the cultures of b), c), and c1) and performing an isolation step to purify the SNAPPs from the cultures of b), c), and c1); e1) quantifying the amount of SNAPPs isolated in d1) from the cultures of b), c), and c1); and f1) determining that the test compound is a stimulator of NMP mediated production of SNAPP secretion when the quantity of SNAPPs isolated from both b) and c1) are significantly increased when compared with the amount of SNAPPs in c).
 14. The method of claim 12, wherein the quantification of SNAPPs in the sample is performed using HPLC (LC-MALDI) or fractionation of an HPLC column directly into an electrospray mass spectrometer (LC/MS-ESI).
 15. A method for screening for compounds which inhibit NMP mediated production of secreted neuronal-activity induced proteasomal peptides (SNAPPs) comprising the steps of: a) providing a plurality of in vitro cultures comprising a plurality of neurons in a growth medium; b) providing one or more test cultures by contacting the neurons of at least a first culture with a test compound and with a known neuronal inhibitor for a period of time sufficient to allow NMP mediated production of SNAPPs into the growth medium; c) providing a negative control by contacting the neurons of at least a second culture for a period of time sufficient with a carrier or vehicle which will not inhibit NMP mediated production of SNAPPs into the growth medium; d) providing a positive control by stimulating the neurons of a third culture for a period of time sufficient with a known neuronal inhibitor to allow NMP mediated production of SNAPPs into the growth medium; e) removing at least a portion of the growth medium of the cultures of b) to d) and performing an isolation step to purify the SNAPPs from the cultures of b) to d); f) quantifying the amount of SNAPPs isolated in e) from the cultures of b) to d); and g) determining that the test compound is an inhibitor of NMP mediated production of SNAPP secretion when the quantity of SNAPPs isolated from b) are significantly reduced when compared with the amount of SNAPPs in c) and/or d).
 16. The method of claim 15, wherein the quantification of SNAPPs in the sample is performed using HPLC (LC-MALDI) or fractionation of an HPLC column directly into an electrospray mass spectrometer (LC/MS-ESI).
 17. A method for inhibiting secreted neuronal-activity induced proteasomal peptides (SNAPPs) in a neuronal cell or population of cells comprising contacting the cell or population of cells with an effective amount of at least one proteasomal inhibitor for a time sufficient to inhibit secretion of SNAPPs.
 18. The method of claim 17, wherein the cell or population of cells is in vitro.
 19. The method of claim 17, wherein the cell or population of cells is in vivo.
 20. The method of claim 17, wherein the proteasomal inhibitor is selected from the group consisting of peptide aldehydes, peptide boronates, and nonpeptide inhibitors.
 21. The method of claim 20, wherein the peptide aldehydes are MG-132, MG-132, MG-115, ALLN, or PSI, biotin-epoxomicin.
 22. The method of claim 20, wherein the peptide boronate is bortezomib/PS-341. 23.-28. (canceled) 